JP2005010459A - Image display device and game machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image display device which enables a stereoscopic image to be observed from a plurality of observing positions with simple constitution, and provide a game machine. <P>SOLUTION: A light emitting unit 23 is arranged over in a right-and-left direction with respect to a liquid crystal display panel, and light emitting elements 22 are constituted in a polygonal line state in a condition that they are positioned nearly at an equal distance from the center of a Fresnel lens. In a polarizing filter 26, a changing area 63 is constituted by adjoining a 1st polarizing filter 61 changing light from the unit 23 to light of a specified polarization direction, and a 2nd polarizing filter 62 changing the light from the unit 23 to light of a polarization direction perpendicular to the specified polarization direction, and the plurality of changing areas 63 are provided in a condition that the 1st and the 2nd polarizing filters 61 and 62 are alternately arranged in the longitudinal direction of the light emitting unit 23. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an image display device that allows an observer to stereoscopically view without wearing special glasses, and a gaming machine using the image display device.
[0002]
[Prior art]
Conventionally, a so-called 3D image display device has been developed in which a display image can be viewed stereoscopically. For example, a parallax barrier method, a lenticular method, There is an image display device based on a method (for example, refer to Patent Document 1) that expands a stereoscopically visible range and can display a normal planar image.
[0003]
In addition, in the image display device, an observer-following image in which the restriction on the observation position of the stereoscopic image and the number of observers is relaxed by moving a projector that displays the stereoscopic image according to the position of the observer. A display device has been proposed (see, for example, Patent Document 2). Furthermore, by detecting the position of the face of the observer and displaying a backlight control image based on the detection result, so-called crosstalk in which an image presented to one observation eye leaks to the other observation eye is made difficult to occur. An image display device has been proposed (see, for example, Patent Document 3).
[0004]
[Patent Document 1]
JP-A-8-262370 (2nd page, FIG. 3)
[Patent Document 2]
Japanese Patent Laid-Open No. 5-241099 (2nd page, FIG. 1)
[Patent Document 3]
JP-A-10-150676 (2nd page, FIG. 11)
[0005]
[Problems to be solved by the invention]
However, the above-described image display device that can follow the position of the observer is difficult to put together in a compact configuration because it includes a plurality of projectors or a display device for displaying a backlight control image. For this reason, the image display device is easily limited by the installation location and cost, and the range of use tends to be limited.
[0006]
By the way, recently, an image display device capable of displaying a stereoscopic image is provided in a gaming machine represented by a pachinko gaming machine. However, a game machine equipped with a conventional image display device has a limited range in which stereoscopic viewing is possible. Specifically, the player cannot stereoscopically view the image unless facing the front of the gaming machine, and cannot enjoy the stereoscopic image if the posture is lost in the left-right direction. For example, when enjoying a game with a game machine adjacent to a friend or the like, the images of the game machines of each other cannot be stereoscopically viewed from the adjacent position. Therefore, it is difficult for a conventional gaming machine to meet a player's request to share the fun of gaming unique to stereoscopic images.
[0007]
In order to solve this problem, it is conceivable to equip a gaming machine with the above-described observer-following type image display device. However, in general, an island facility of a gaming store has a limited gaming machine installation space. If an image display device having such a large-scale configuration is provided in a gaming machine, the installation on the island facility will be hindered.
[0008]
Therefore, the present invention has been made in view of the above circumstances, and an object of the present invention is to provide an image display device and a gaming machine that can observe a stereoscopic image from a plurality of observation positions with a simple configuration.
[0009]
[Means for Solving the Problems]
The present invention has been proposed in order to achieve the above object, and the liquid crystal display panel according to claim 1 is capable of transmitting light irradiated from the back.
A light source that irradiates the liquid crystal display panel with light having a specific polarization direction and light having a polarization direction orthogonal to the specific polarization direction;
A first region disposed between the liquid crystal display panel and the light source and transmitting light of the specific polarization direction; and a second region transmitting light of a polarization direction orthogonal to the specific polarization direction, A filter provided repeatedly in the vertical direction,
The light source includes a linear light emitting source that emits light whose polarization direction is not specified, light that is not specified in polarization direction, light in the specific polarization direction, and light in a polarization direction orthogonal to the specific polarization direction. In an image display device configured to include: a polarizing unit that converts and outputs light; and an optical unit that refracts light in different polarization directions in a direction that reaches the left and right eyes and irradiates the liquid crystal display panel.
The linear light source is arranged in the left-right direction with respect to the liquid crystal display panel, and the light emitting part is configured in a curved line or a broken line in a state of being located at an approximately equal distance from the center of the optical means,
The polarization means includes a first conversion region that converts light from the linear light source into light having the specific polarization direction, and light having a polarization direction orthogonal to the specific polarization direction. A second conversion region that converts light is adjacent to each other to form a conversion region pair,
An image display device comprising a plurality of pairs of conversion areas in a state where the first conversion areas and the second conversion areas are alternately arranged along the longitudinal direction of the linear light emitting source.
[0010]
According to a second aspect of the present invention, the linear light emitting source is composed of a plurality of point light emitting elements arranged in a line, and a prism that increases the luminous intensity by narrowing the irradiation range of the point light emitting elements. For each light emitting element,
The polarizing means includes a first polarizing filter that constitutes the first conversion region and a second polarizing filter that constitutes the second conversion region on a translucent plate that is long in the same direction as the linear light source. Are formed side by side to form the transformation region pair,
The said 1st polarizing filter and the said 2nd polarizing filter were equipped with two or more said conversion area | region pairs in the state which were located in a line along the longitudinal direction of the said linear light source. An image display device.
[0011]
According to a third aspect of the present invention, the linear light-emitting source includes a plurality of point-like light-emitting elements arranged in a line, and a prism that increases the luminous intensity by narrowing the irradiation range of the point-like light-emitting elements. For each light emitting element,
The prism includes an incident surface on which light from a point light emitting element is incident, and an emission surface that emits light that has been incident from the incident surface and whose optical path is corrected,
A prism block is configured by connecting a plurality of the prisms,
The polarizing means forms the conversion area pair by forming the first conversion area and the second conversion area adjacent to each other along the longitudinal direction of the linear light source on the exit surface of the prism block,
The image display according to claim 1, wherein a plurality of the conversion area pairs are provided by arranging a plurality of the prism blocks in a state where the first conversion areas and the second conversion areas are alternately arranged. Device.
[0012]
According to a fourth aspect of the present invention, the linear light emitting source is composed of a plurality of point light emitting elements arranged in a line, and the first prism or the first prism for increasing the luminous intensity by narrowing the irradiation range of the point light emitting elements. A second prism is provided for each point light emitting element,
The first prism and the second prism each include an incident surface on which light from a point light emitting element is incident, and an output surface that emits light having an optical path corrected by entering from the incident surface,
The polarizing means forms the first conversion region on the exit surface of the first prism, forms the second conversion region on the exit surface of the second prism, and pairs the first prism and the second prism. By configuring the conversion area pair, a plurality of the conversion area pairs in a state where the first prism and the second prism are alternately arranged,
The image display apparatus according to claim 1, further comprising a light emission control unit that controls light emission of the point light emitting element.
[0013]
The liquid crystal display panel according to claim 5 is capable of transmitting light irradiated from the rear, and
A light source that irradiates the liquid crystal display panel with light having a specific polarization direction and light having a polarization direction orthogonal to the specific polarization direction;
A first region disposed between the liquid crystal display panel and the light source and transmitting light of the specific polarization direction; and a second region transmitting light of a polarization direction orthogonal to the specific polarization direction, A filter provided repeatedly in the vertical direction,
The light source includes a linear light emitting source that emits light whose polarization direction is not specified, light that is not specified in polarization direction, light in the specific polarization direction, and light in a polarization direction orthogonal to the specific polarization direction. In an image display device configured to include: a polarizing unit that converts and outputs light; and an optical unit that refracts light in different polarization directions in a direction that reaches the left and right eyes and irradiates the liquid crystal display panel.
The linear light-emitting source is arranged in the left-right direction with respect to the liquid crystal display panel, and a plurality of point-like light-emitting elements are arranged to form a first light-emitting element array and a second light-emitting element array, , Arranged in parallel with each other, and configured in a curved line or a broken line in a state of being located at an approximately equal distance from the center of the optical means
The first light emitting element row includes a first prism for each point light emitting element row that increases the luminous intensity by narrowing the irradiation range of the point light emitting elements.
The second light emitting element array includes a second prism for each point light emitting element array that increases the luminous intensity by narrowing the irradiation range of the point light emitting elements,
The first prism and the second prism each include an incident surface on which light from a point light emitting element is incident, and an output surface that emits light having an optical path corrected by entering from the incident surface,
The polarizing means includes a first conversion region for converting light whose polarization direction is not specified into light of the specific polarization direction on the exit surface of the first prism, and the exit surface of the second prism includes the A second conversion region that converts light whose polarization direction is not specified into light having a polarization direction orthogonal to the specific polarization direction; and the first conversion region and the second conversion region are arranged in the longitudinal direction of the linear light emitting source. In parallel along the direction,
An image display device comprising light emission control means for controlling light emission of the point light emitting element.
[0014]
According to a sixth aspect of the present invention, the light emission control means has a boundary between a range in which light having a specific polarization direction is emitted from the polarization means and a range in which light having a polarization direction orthogonal to the specific polarization direction is emitted. Boundary setting means for setting
6. The point light emitting element corresponding to the first prism emits light on one side of the boundary, and the point light emitting element corresponding to the second prism emits light on the other side. This is an image display device.
[0015]
The thing of Claim 7 is equipped with the observer detection means which can detect an observer's position,
The image display device according to claim 4, wherein the light emission control unit controls light emission of the point light emitting element based on a detection result of an observer position by the observer detection unit. It is.
[0016]
When the variable display game in which the variable display game which variably displays the identification information is executed is provided, and the identification information displayed as a result mode of the variable display game becomes a specific display mode A gaming machine that gives a predetermined gaming value to
A gaming machine comprising the variable display device using the image display device according to any one of claims 1 to 7.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment in which an image display device is provided in a pachinko gaming machine that is a typical gaming machine will be described with reference to the drawings. FIG. 1 is a front view of a game board of a pachinko machine.
[0018]
As shown in FIG. 1, the game board 1 of the pachinko gaming machine has a substantially circular shape by fixing a guide rail 5, a game area partition member 6 and the like to the surface of a rectangular game board body 2 made of plywood or plastic. A game area 7 having a shape is defined. In the gaming area 1, a center case 8 is disposed from substantially the center to the opposite side of the guide rail 5 (right side in the figure) in the gaming area 7. The image display device (variable display device) 9 is provided on the front surface so as to be positioned at approximately the center of the front. Further, the game board 1 has a tulip-type start winning tool (a kind of winning tool) 10 disposed below the image display device 9, and the game is displayed below the start winning tool 10 according to the operation result of the image display device 9. A special variable winning device (large winning opening) 11 that can be converted into a first state in which a ball is not received and a second state in which a ball is easily received is provided. In addition to this, the game board 1 includes a general winning device (a type of winning device) 12, a windmill 13 for changing the flow direction of the game ball, an obstacle nail (not shown), and various lamps that display various decorations by light emission. The LED 14 and an out port 15 for collecting game balls that have flowed down without winning are provided.
[0019]
The center case 8 has a rectangular opening window 18 at the center, and includes a mounting board 19 that is attached to the surface of the game board 1, and an armor part 20 that imitates wave droplets is projected forward on the mounting board 19. The game ball guided to the game area 7 by the guide rail 5 is configured not to directly collide with the image display device 9.
[0020]
Next, a specific structure of the image display device 9 will be described.
As shown in FIGS. 2 and 3, the image display device 9 includes a housing 20 formed of resin, a display unit 21 provided on the front surface of the housing 20, and a plurality of light emitting elements 22 (see FIG. 5). ) In parallel with each other, a light emitting unit 23 (corresponding to the linear light source of the present invention) housed in the housing 20, a reflecting mirror 24 that reflects light from the light emitting unit 23 to the display unit 21, and a light emitting element For example, a Fresnel lens 25 (corresponding to the optical means of the present invention) that refracts light into light that reaches the left or right eye of the observer into, for example, substantially parallel light. The image display device 9 includes a light emitting unit 23, a polarizing filter 26 (described later) provided in the light emitting unit 23, and a Fresnel lens 25 to constitute a light source 27, and a liquid crystal display of the display unit 21. The panel 28 (described later) can be irradiated with light having a specific polarization direction and light having a polarization direction orthogonal to the specific polarization direction (see FIGS. 11 to 13. This will be described in detail later. ).
[0021]
As shown in FIG. 3, the housing 20 has a rear case 31 having a front surface opened and a rear upper surface inclined downward, and a frame shape attached along the left and right sides and the upper opening edges of the rear case 31. The front frame 32 and a front cover 33 attached below the front frame 32 so as to close the lower opening of the rear case 31. And the housing | casing 20 opens the big rectangular-shaped opening part 34 in the front surface of the said housing | casing 20, ie, the front frame 32, and attaches the diffuser 35 and the display part 21 in the state which plugged up the front side of this opening part 34, this The periphery of the diffuser 35 and the display unit 21 is fixed from the front by a frame-shaped display unit holding frame 36.
[0022]
The display unit 21 is a member capable of transmitting light from a light emitting unit 23 described later, and is a fine retardation plate from the light incident side of the light emitting unit 23, that is, from the back side (right side in the figure) of the image display device 9. 39 (corresponding to a part of the filter of the present invention), the first polarizing sheet 40 (corresponding to a part of the filter of the present invention), the liquid crystal display panel 28, and the second polarizing sheet 41 are provided in a polymerized state in this order. . That is, the fine retardation plate 39 and the first polarizing sheet 40 are disposed between the liquid crystal display panel 28 and the light source 27. The fine retardation plate 39 alternately includes first regions 39a and second regions 39b having different polarization characteristics, and is arranged in the vertical direction at substantially the same repetition pitch as the horizontal scanning lines of the liquid crystal display panel 28. . The first region 39a and the portion of the first polarizing sheet 40 facing the first region 39a transmit light polarized in a specific direction when irradiated with light emitted from the light emitting unit 23 described later. . The second region 39b and the portion of the first polarizing sheet 40 that faces the second region 39b are irradiated with light emitted from the light emitting unit 23, and the polarization direction is orthogonal to the light having the specific polarization direction. Transmits light having The liquid crystal display panel 28 is a member that can transmit light emitted from the rear, displays an image for the left eye on a scanning line corresponding to the first region 39a of the fine phase difference plate 39, and the second region 39b. The right-eye image is displayed on the scanning line corresponding to. That is, the liquid crystal display panel 28 is configured to display the left-eye image and the right-eye image alternately in the vertical direction by one scanning line (see FIG. 4).
[0023]
In addition, the housing 20 is attached with a Fresnel lens 25 in a state in which the rear side of the opening 34 is closed, and the periphery of the Fresnel lens 25 is fixed from the rear by a lens holder 43. The Fresnel lens 25 is attached with the focal point located at the rear, and converts light incident from the rear into substantially parallel light or light narrowed down toward the front, in other words, light having different polarization directions. Is refracted in a direction to reach the left and right eyes, and is radiated to the front display unit 21, that is, the liquid crystal display panel 28 (see FIG. 6).
[0024]
The reflecting mirror 24 is a mirror for reflecting light from the light emitting unit 23, which will be described later, to the display unit 21, and is attached in a state where it is inclined downward along the inclined wall portion 20a on the inner upper side of the housing 20. It has been. The reflecting mirror 24 reflects most of the light (about 90% to 95%) emitted from the light emitting element 22 of the light emitting unit 23 to the display unit 21 as reflected light, and is emitted from the light emitting element 22 of the light emitting unit 23. This is a surface reflecting mirror configured so that a part (approximately 10% to 5%) of the transmitted light can be transmitted to the back side as transmitted light.
[0025]
Next, the light emitting unit 23 will be described.
The light emitting unit 23 is a unit for irradiating the liquid crystal display panel 28 with light. The light emitting unit 23 is disposed on the inner lower part of the rear case 31, that is, behind the front cover 33 with the light emitting element 22 facing the reflecting mirror 24 and extending in the left-right direction with respect to the liquid crystal display panel 28.
[0026]
FIG. 5 is an exploded perspective view seen from the rear of the light emitting unit 23. As shown in FIG. 5, the light emitting unit 23 houses a horizontally long light emitting substrate 46 in a light emitting unit case 45 (a case lid 45a and a case main body 45b) that can be divided into front and rear parts. A light emitting element 22 (corresponding to the point light emitting element of the present invention) such as LEDs (for example, white LED) is arranged in parallel at a predetermined arrangement pitch along the longitudinal direction of the light emitting substrate 46 to emit light linearly. The light emitting part of the light source is formed. The light emitting unit 23 includes a prism array 48 on the light emitting element 22, and a polarizing filter 26 (corresponding to the polarizing means of the present invention) elongated in the direction in which the light emitting elements 22 are arranged above the light emitting unit case 45. The filter is held in a state where it is mounted on a filter holding frame (polarizing filter holding frame) 49.
[0027]
As shown in FIG. 6, the light emitting substrate 46 assumes a virtual arc line A in which the optical path lengths to the center of the Fresnel lens 25 are equidistant, and is in a state along a virtual broken line L that approximates the virtual arc line A. It is bent. Accordingly, the light emitting elements 22 on the light emitting substrate 46 are arranged on the virtual broken line L, and the optical axis of the light from the light emitting elements 22 is positioned near the center of the Fresnel lens 25. In the present embodiment, the light-emitting substrate 46 is provided in a state where three rows of light-emitting elements 22 arranged in a straight line are connected in series by bending into three. The row 22L of the light emitting elements 22 positioned on the left side of the image display device 9 emits light toward the front right side of the image display device 9, and the row 22R of the right light emitting elements 22 displays the image. Light is emitted toward the front left side of the device 9, and the row 22 </ b> C of the central light emitting element 22 is arranged to emit light toward the front center of the image display device 9.
[0028]
The prism array 48 is for narrowing down the light incident from the light emitting element 22 and suitably emitting it to the liquid crystal display panel 28. As shown in FIGS. 5 and 7, the prism row 48 has a flat plate portion 52 disposed substantially parallel to the row of the light emitting substrate 46 and the light emitting element 22, and the light of the prism 53 described later on the surface of the flat plate portion 52. Are formed. In addition, the prism array 48 includes a plurality of prisms 53 protruding in a comb-like shape (integral molding) from the back surface of the flat plate portion 52 toward the respective light emitting elements 22 to form an optical path. The light incident surface 55 is in contact with the light emitting element 22 (see FIG. 8). That is, the prism row 48 is a member in which the prisms 53 for the respective light emitting elements 22 are connected, and the incident surfaces 55 are provided one-to-one with respect to the light emitting elements 22. The prism array 48 is configured by a curved surface in which the side surface of each prism 53 is formed by a Bezier curve, and the light incident from the incident surface 55 is totally reflected by the side surface of the prism 53, and the light is incident from other than the emission surface 54. It does not transmit to the outside of the prism array 48 (see FIG. 8B). In this manner, the prism array 48 restricts the light from spreading in the vicinity of the light emitting element 22 by the side surface portion (that is, the optical path correction unit) of the prism 53, and narrows the irradiation range of the light optical path. It can correct | amend so that a luminous intensity may be raised and can radiate | emit from the output surface 54, without weakening on the way.
[0029]
Note that the prism array 48 of the present embodiment is divided into three, a left prism array 48L, a central prism array 48C, and a right prism array 48R, with the bent portion of the light emitting substrate 46 as a boundary. The prism column 48 corrects the light from the column 22L of the left light emitting element 22 with the left prism column 48L, corrects the light from the column 22C of the central light emitting element 22 with the center prism column 48C, and corrects the right prism column. The light from the row 22R of the right light emitting element 22 can be corrected by 48R.
[0030]
The polarizing filter 26 is a translucent plate that polarizes the light from the light emitting element 22 in different directions for the left eye and the right eye, and is on the optical path from the light emitting element 22 to the Fresnel lens 25, and is a light emitting unit. (Linear light emission source) 23 is provided on the light emission side. As shown in FIG. 9A, the polarizing filter 26 is a first polarizing filter 61 (corresponding to the first conversion region of the present invention) that forms a left-eye polarizing portion on the surface of a horizontally long and transparent base film 60. And a second polarizing filter 62 (corresponding to the second conversion region of the present invention) that forms the right-eye polarizing section. Specifically, the polarizing filter 26 includes a plurality of (in the present embodiment) a conversion region pair 63 in which the first polarizing filter 61 and the second polarizing filter 62 are adjacent to each other in the left-right direction (longitudinal direction) of the base film 60. The three conversion region pairs 63 are in a state in which the first polarizing filter 61 and the second polarizing filter 62 are alternately arranged along the longitudinal direction of the light emitting unit 23, specifically toward the front of the image display device 9. From the right side, the polarizing filters 61 and 62 are pasted through a transparent adhesive or the like in a state of being aligned with the first polarizing filter 61, the second polarizing filter 62, the first polarizing filter 61, the second polarizing filter 62,. (See FIG. 9B). In the polarizing filter 26, the polarization directions of light transmitted through the first polarizing filter 61 and the second polarizing filter 62 are different from each other. Specifically, the polarization filter 26 specifies the light emitted from the light emitting element 22, that is, the light whose polarization direction is not specified, by shifting the polarization directions of the first polarization filter 61 and the second polarization filter 62 by 90 degrees. It is set so that it is converted into light having a polarization direction of 2 and light having a polarization direction orthogonal to the specific polarization direction and output (transmits).
[0031]
In addition, as shown in FIG. 9C, the polarizing filter 26 has a polarizing film 64 of the same size as the table attached to a single base film 60, and the first polarizing filter 61 on the surface of the polarizing film 64. Alternatively, the two types of polarizing filters 61 and 62 may be alternately formed by attaching a retardation film 65 to a region where one of the second polarizing filters 62 is to be formed.
[0032]
The polarizing filter 26 is held by the filter holding frame 49 with the emission surface 54 of the prism row 48 facing downward, and the left side of the three conversion area pairs 63 facing the front of the image display device 9 is left. The conversion area pair 63L converts the light emitted from the left prism array 48L (that is, the light emitted from the left light emitting element array 22L), and the central conversion area pair 63C outputs the light emitted from the central prism array 48C (that is, light). Light emitted from the central light emitting element row 22C), and light emitted from the right prism row 48R (that is, light emitted from the right light emitting element row 22R) is converted by the right conversion region pair 63R. ing.
[0033]
And the light emission unit 23 is equipped with the structure which flows cooling air inside. Specifically, the light emitting unit 23 opens the intake ports 68 on both sides of the case lid 45a located on the front side, and the exhaust ports 69 on the center portion in the left-right direction of the case body 45b located on the rear side. 68 and the exhaust port 69 are communicated with each other through the space inside the light emitting unit case 45. The light emitting unit 23 communicates the intake port 68 with the intake slit 70 formed in the front cover 33 and communicates the exhaust port 69 with the exhaust fan 71 provided outside the rear case 31 via the duct 72. ing. With such a configuration, the light emitting unit 23 can cool the light emitting element 22 by taking in air from the front of the image display device 9, forcing the air around the light emitting element 22 and exhausting the air from the exhaust fan 71. It is like that.
[0034]
Next, the game control device 75 that controls the game of the pachinko gaming machine and the control contents will be described. FIG. 10 is a configuration diagram of a control device provided in the pachinko gaming machine, and mainly shows a control system portion centering on the game control device 75 as a block configuration diagram.
[0035]
The game control device 75 functions as a main control device (control means) for comprehensively controlling the game, and includes a game microcomputer 76, an input interface 77, an output interface 78, and the like. The game microcomputer 76 includes a CPU that controls game control, a ROM that stores a program for game control, and a RAM that is used as a work area during game control. The gaming microcomputer 76 is provided with an external communication terminal 79 so that an identification number uniquely set in the gaming microcomputer 76 can be output from the external communication terminal 79. Specifically, the pachinko gaming machine can be identified by connecting an inspection device or a management computer (not shown, so-called hall control) to the external communication terminal 79 and reading the identification number. ing.
[0036]
The game control device 75 configured as described above is supplied from various detection devices (general winning opening sensor 81, special symbol start sensor 82, normal symbol start sensor 83, count sensor 84, continuation sensor 85) via the input interface 77. In response to the detection signal, various processes such as a jackpot game (special game) are performed. Then, in addition to various subordinate control devices (display control device 87, discharge control device 88, decoration control device 92, sound control device 93), command signals are transmitted to the ordinary electric accessory solenoid 89, the special prize opening solenoid 90, etc. , Control the game centrally.
[0037]
Then, the game control device 75 transmits, to the display control device 87, a variable display command, an identification information command, a confirmation command, a demonstration display command, a fanfare command, a jackpot command, an error command, and the like as a display control command signal. Further, a command signal for changing the display mode according to the difference in the gaming state such as the normal gaming state, the probability variation state, the variation time shortening state, etc. is also transmitted.
[0038]
The discharge control device 88 controls the operation of the payout unit based on a prize ball command signal from the game control device 75 or a ball rental request from the card unit (ball rental unit) 91, and discharges the prize ball or the ball rental. Let it be done.
[0039]
The decoration control device 92 controls decoration light emitting devices such as decoration lamps and LEDs (decoration lamps in the center case 8, lamps / LEDs 14 in the game area 7, etc.) based on the decoration control command signal from the display control device 87. To do.
[0040]
The sound control device 93 controls the sound effect output from the speaker based on the sound control command signal from the display control device 87.
[0041]
The display control device 87 is a device for controlling the image display device 9. Specifically, the display control device 87 is an LCD driver (LCDDRV) for driving the liquid crystal display panel 28 of the image display device 9. And a BL driver (BLDRV) for driving the light emitting unit 23 is connected. Note that a composite conversion device 96 that combines the left-eye image and the right-eye image is connected between the LCD driver (LCDDRV) and the display control device 87. The display control device 87 includes a display control CPU 94, a ROM storing programs and image data (symbol data, background image data, moving image character data, texture data, etc.), and a work area when the display control CPU 94 operates. And a RAM provided with a frame buffer for temporarily storing image data displayed on the image display device 9, a GDP (Graphic Display Processor) 95, and the like.
[0042]
The display control CPU 94 executes a program stored in the ROM, and based on a signal from the game control device 75, image control information (symbol display information composed of sprite data, polygon data, etc., according to the game state, Background screen information, moving image object screen information, etc.), and instructs the GDP 95 to generate an image signal to be displayed on the image display device 9.
[0043]
Based on the image data stored in the ROM and the contents calculated by the display control CPU 94, the GDP 95 performs, for example, polygon drawing (or normal bitmap drawing) of an image and a predetermined value for each polygon. The texture is pasted and stored in a RAM as a frame buffer. Then, the GDP 95 transmits the image stored in the RAM to the image display device 9 via the composite conversion device 96 at a predetermined timing (timing of the vertical synchronization signal V_SYNC and the horizontal synchronization signal H_SYNC) to display the image.
[0044]
The GDP 95 performs drawing processing such as point drawing, line drawing, triangle drawing, polygon drawing, texture mapping, alpha blending, shading processing (glow shading, etc.), hidden surface removal (Z buffer processing, etc.), and the like. The image signal subjected to these drawing processes is output to the image display device 9.
[0045]
Here, the display control device 87 may set a plurality of frame buffers in respective predetermined storage areas of the RAM, and output them to the image display device 9 in a state in which arbitrary images are overlaid by the GDP 95 (overlay). it can.
[0046]
Further, the GDP 95 is connected to an oscillator that supplies a clock signal. The clock signal generated by this oscillator defines the operating period of GDP95. Based on this clock signal, a vertical synchronization signal (V_SYNC) and a horizontal synchronization signal (H_SYNC) are generated and output to the image display device 9 as timing signals.
[0047]
The display control device 87 is provided with a buffer (signal transmission direction restricting means) at the connection interface with the game control device 75, and the display from the game control device 75 is performed in the communication between the game control device 75 and the display control device 87. Only signal input to the control device 87 is allowed, and signal output from the display control device 87 to the game control device 75 is prohibited.
[0048]
In this embodiment, the decoration control device 92 and the sound control device 93 are provided separately from the display control device 87. However, among the subordinate control devices, the decoration control device 92 and the sound control device 93 are included in the display control device 87. In addition, the decoration control device 92 and the sound control device 93 may be configured integrally with the display control device 87.
[0049]
Further, the decoration control device 92 and the sound control device 93 may be configured to be connected to the display control device 87 without being directly connected to the game control device 75.
[0050]
Next, stereoscopic display of the image display device 9 will be described.
When light is emitted from the light emitting element 22 in the image display device 9 having the above-described configuration, the light is transmitted through the polarizing filter 26 and spread radially as shown in FIGS. Actually, the light emitting elements 22 of the light emitting element arrays 22L, 22C, and 22R emit light at the same time. However, in order to make the optical path easy to understand, the optical path of the light from the central light emitting element array 22C is shown in FIG. FIG. 12 shows an optical path of light from the left light emitting element array 22L, and FIG. 13 shows an optical path of light from the right light emitting element array 22R. Hereinafter, the three-dimensional display will be described focusing on the light from the central light emitting element array 22C, but the left and right light emitting element arrays 22L and 22R are substantially the same, and thus detailed description thereof will be omitted.
[0051]
Of the light that spreads radially, light that has passed through the first polarizing filter (first conversion region, left-eye polarizing unit) 61 in the central conversion region 83C of the polarizing filter 26 (the center of the optical path is indicated by a one-dot chain line). Is refracted so as to reach the left eye of the observer through the Fresnel lens 25, for example, substantially parallel light (indicated by a solid line arrow) or light gradually narrowed toward the position of the left eye of the observer. You can change direction. Of the light emitted from the Fresnel lens 25, the light incident on the first region 39a of the fine phase difference plate 39 is transmitted with the polarization axis rotated by 90 degrees. The light emitted from the first region 39a passes through the first polarizing sheet 40, the liquid crystal display panel 28, and the second polarizing sheet 41 substantially vertically (slightly from the right side to the left side) and is positioned in front of the image display device 9. It reaches the left eye of the observer. In this way, among the images displayed on the display element of the liquid crystal display panel 28, the left-eye image displayed at the position corresponding to the first region 39a is applied to the left eye of the observer facing the image display device 9. To reach.
[0052]
Note that the second regions 39b arranged alternately with the first regions 39a of the fine retardation film 39 do not change the polarization axis of the transmitted light. Therefore, even if the light passes through the first polarizing filter 61 of the polarizing filter 26, the light emitted from the second region 39b has a polarization direction shifted by 90 degrees with respect to the light from the first region 39a. One polarizing sheet 40 is not transmitted. As a result, among the images displayed on the display element of the liquid crystal display panel 28, the right-eye image displayed at the position corresponding to the second region 39b is applied to the left eye of the observer facing the image display device 9. Not reach.
[0053]
On the other hand, light transmitted through the second polarizing filter (second conversion region, right-eye polarizing unit) 62 in the central conversion region 83C of the polarizing filter 26 (the center of the optical path is indicated by a thick broken line) is observed by the Fresnel lens 25. For example, substantially parallel light (indicated by a thick arrow) or light that is gradually narrowed toward the right eye position of the observer. Of the light emitted from the Fresnel lens 25, the light incident on the second region 39 b of the fine phase difference plate 39 transmits light having the same polarization direction as that of the second polarizing filter 62 of the polarizing filter 26. The light emitted from the second region 39b passes through the first polarizing sheet 40, the liquid crystal display panel 28, and the second polarizing sheet 41 substantially vertically (slightly left to right) and is positioned at the front center of the image display device 9. It reaches the observer's right eye. In this way, among the images displayed on the display elements of the liquid crystal display panel 28, the right-eye image displayed at the position corresponding to the second region 39b is applied to the right eye of the observer facing the image display device 9. To reach.
[0054]
In addition, the 1st area | region 39a arrange | positioned alternately with the 2nd area | region 39b of the fine phase difference plate 39 is comprised so that the polarization axis of the transmitted light may be rotated 90 degree | times as above-mentioned. Therefore, even if the light passes through the second polarizing filter 62 of the polarizing filter 26, the light emitted from the first region 39a has a polarization direction shifted by 90 degrees with respect to the light from the second region 39b. One polarizing sheet 40 is not transmitted. Thus, among the images displayed on the display element of the liquid crystal display panel 28, the image for the left eye displayed at the position corresponding to the first region 39a reaches the right eye of the viewer facing the image display device 9. do not do.
[0055]
In the image display device 9, the right-eye image and the left-eye image of the liquid crystal display panel 28 are shifted left and right to generate binocular parallax, and a stereoscopic image is displayed by adjusting the shift amount. Can do.
[0056]
Specifically, as shown in FIG. 14A, if there is no left-right shift between the right-eye image and the left-eye image, the image display device 9 is an image that does not generate binocular parallax. That is, a two-dimensional planar image is displayed, and this image appears on the display screen.
[0057]
As shown in FIG. 14B, if there is a left-right shift x1 between the right-eye image and the left-eye image, the image display device 9 can generate an image that generates binocular parallax, that is, a three-dimensional stereoscopic image. Is displayed. Further, in a state where the right-eye image is located on the side opposite to the right eye (left side in the figure) and the left-eye image is located on the opposite side (right side in the figure), the image display device 9 It is possible to display an image with a three-dimensional effect such that the image appears at a position closer to the front side by y1 than the display screen.
[0058]
Then, as shown in FIG. 14C, there is a left-right shift x2 between the right-eye image and the left-eye image, and the right-eye image is located on the right side and the left-eye image is located on the left side. For example, the image display device 9 displays an image that generates binocular parallax, that is, a three-dimensional stereoscopic image, and this image appears at a position on the back side by y2 with respect to the display screen, and has a stereoscopic effect that pulls down. An image can be displayed.
[0059]
Further, the image display device 9 is described above even when the light from the left light emitting element array 22L shown in FIG. 12 is converted by the left conversion region pair 63L and irradiated to the right eye image and the left eye image. A three-dimensional image can be caused to appear by the same action as the light irradiation by the central light emitting element array 22C. At this time, since the left light emitting element row 22L emits light toward the front right side of the liquid crystal display panel 28, the image display device 9 displays a stereoscopic image that appears by the light of the left light emitting element row 22L in front of the image display device 9. A stereoscopic image can be shown to an observer who observes on the right side (for example, a person who is watching a game or a player who is playing a game with his / her posture lost).
[0060]
The image display device 9 is described above even when the light from the right light emitting element array 22R shown in FIG. 13 is converted by the right conversion region pair 63R and irradiated to the right eye image and the left eye image. A three-dimensional image can be caused to appear by the same action as the light irradiation by the central light emitting element array 22C. At this time, the right light emitting element array 22R emits light toward the front right side of the liquid crystal display panel 28, so that the image display device 9 displays a stereoscopic image that appears by the light of the right light emitting element array 22R in front of the image display apparatus 9. A three-dimensional image can be shown to an observer who observes on the left side (for example, a person who is watching a game or a player who is playing a game with a broken posture).
[0061]
Thus, the image display device 9 can display a stereoscopic image not only from the front of the game board 1 of the pachinko gaming machine but also from both the left and right sides. Therefore, even if the player relaxes and loses his / her posture, the stereoscopic image can be viewed, and the interest of the game can be prevented from being impaired. In addition, when enjoying a game next to a friend or the like, it is possible to view a stereoscopic image that is being played with each other and view the stereoscopic image from the adjacent position, thereby sharing the interests of the game.
[0062]
Furthermore, the image display device 9 that can be stereoscopically viewed from a plurality of positions can be realized with a simple configuration without requiring large-scale equipment. Therefore, even if the installation space of the pachinko gaming machine of the island facility (pachinko gaming machine installation facility) is limited, the pachinko gaming machine can be installed without causing the image display device 9 to hinder.
[0063]
In the above embodiment, a linear light source that generates linear light by arranging the light emitting elements 22 in a polygonal line as a light source is applied. However, the present invention is not limited to this, and the cold cathode The linear light emitting source may be formed by a single light emitting element such as a tube (CCFL).
[0064]
Further, in the above-described embodiment, the light emitting unit 23 is provided with the light emitting elements 22 arranged on the virtual broken line L, but the present invention is not limited to this. For example, the light emitting unit 23 may arrange the light emitting elements 22 on a virtual arc line in which the optical path lengths to the center of the Fresnel lens 25 are approximately equidistant. That is, the light emitting substrate 46 may be curved in a state along a virtual arc line in which the optical path lengths to the center of the Fresnel lens 25 are equidistant (none is shown). Thus, by configuring the light emitting unit 23 in a state where the light emitting elements 22 are arranged on the virtual arc line, the light of the light emitting elements 22 can be irradiated onto the display unit 21 (the liquid crystal display panel 28) more efficiently.
[0065]
Further, in the light emitting unit 23 of the above embodiment, the first polarizing filter 61 and the second polarizing filter 62 are formed on the polarizing filter 26. However, the present invention is not limited to this, and the first polarizing filter is formed on the emission surface 54 of the prism array 48. A filter 61 and a second polarizing filter 62 may be provided. For example, each of the prism rows 97R, 97C, 97L of the light emitting unit 23 ′ shown in FIG. 15 forms a left-eye polarizing section on the one side (right side in the drawing) from the substantially horizontal center of the emission surface 98. The conversion region pair 63 is configured by forming the first polarizing filter 61 and the second polarizing filter 62 that forms the right-eye polarizing portion on the other side (left side in the figure). When the polarization filters 61 and 62 are formed in the prism row 97 as described above, the polarization filters 61 and 62 can be positioned simultaneously by positioning the prism row 48 with respect to the light emitting element 22. Therefore, the burden of assembling work of the light emitting unit 23 'can be reduced. At this time, it is not necessary to hold the polarizing filter in the filter holding frame 49, but holding the transparent cover film 100 instead is preferable because the prism row 97 can be protected.
[0066]
Further, the first polarizing filter 61 and the second polarizing filter 62 in the prism array 48 may be formed by alternately affixing films having different polarization directions, similarly to the polarizing filters 61 and 62 of the above-described embodiment. Alternatively, the polarizing film 64 may be attached to the entire emission surface 98, and the retardation film 65 may be attached to the region where either the first polarizing filter 61 or the second polarizing filter 62 is formed.
[0067]
By the way, in the said embodiment, the position of the light radiate | emitted from the 1st polarizing filter 61 and the position of the light radiate | emitted from the 2nd polarizing filter 62 were fixed, and the observation position which can be viewed stereoscopically was fixed to the predetermined location. However, the present invention is not limited to this, and the position of the emitted light from each of the polarizing filters 61 and 62 (emission direction) may be changed so that the stereoscopically observable observation position can be moved. Hereinafter, the light emitting unit and the light emission control means for controlling the light emission of the light emitting unit will be described in particular with respect to the image display apparatus of the second embodiment capable of moving the position of the emitted light from each polarizing filter 61, 62.
[0068]
The light emitting unit 103 of the second embodiment shown in FIG. 16 is basically the same as that of the first embodiment, but the shape of the light emitting substrate 104 and the shape of the prism are different. More specifically, the light emitting unit 103 bends the light emitting substrate 104 along a virtual arc line A (see FIG. 6) in which the optical path length to the center of the Fresnel lens 25 is equal, and the light emitting substrate 104 is curved. The light emitting elements (dot light emitting elements) 22 are arranged on the virtual arc line A, and the display unit 21 can be irradiated with light from the light emitting elements 22 more efficiently. The light emitting unit 103 includes a first prism 105 or a second prism 106 on the light emitting element 22, and a cover film 108 that is long and transparent in the direction in which the light emitting elements 22 are arranged above the light emitting unit case 107. The filter is held in a state where it is mounted on the filter holding frame 109.
[0069]
Similar to the prism array 48 of the first embodiment, the first prism 105 and the second prism 106 are for narrowing down the light incident from the light emitting element 22 and suitably emitting it to the liquid crystal display panel 28. As shown in FIG. 17, the first prism 105 and the second prism 106 have a light incident surface 110 at one end (lower end in the figure) and a size substantially equal to the light emitting portion (light emitting surface) of the light emitting element 22. The light emitting surface 111 is formed at the other end (upper end in the figure) in a state that is longer than the incident surface 110. The first prism 105 and the second prism 106 are configured by curved surfaces formed by Bezier curves on the side surfaces, and the light incident from the incident surface 77 is totally reflected by the side surfaces, and the light is incident from other than the emission surface 111. The prisms 105 and 106 are not transmitted to the outside. In this way, the prisms 105 and 106 restrict the light from spreading to the vicinity in the vicinity of the light emitting element 22 by the side surface portion (that is, the optical path correction unit), thereby reducing the light path of the light and narrowing the irradiation range. It can correct | amend so that it may raise and can radiate | emit from the output surface 111, without weakening on the way.
[0070]
Further, the first prism 105 is provided by attaching the first polarizing filter 61 to the emission surface 111, and is configured to convert the light from the light emitting element 22 into a specific polarization direction and emit the light. On the other hand, the second prism 106 includes a second polarizing filter 62 attached to the emission surface 111, and is configured to convert the light from the light emitting element 22 into a polarization direction orthogonal to a specific polarization direction and emit the light. Has been.
[0071]
The light emitting unit 103 according to the present embodiment makes a pair of the first prism 105 and the second prism 106, thereby converting the light output unit 111 from the first polarizing filter 61 and the second polarizing filter 62 on the emission surface 111 of both prisms. A region pair 63 is configured. Further, the light emitting unit 103 has the first prism 105 and the second prism 106 in a state where the incident surface 110 is in contact with the corresponding light emitting element 22, that is, in an arc shape between the Fresnel lens 25 and the light emitting element 22. A plurality of pairs are assembled in a state aligned in the longitudinal direction. In this way, the light emitting unit 103 includes a plurality of conversion region pairs 63 as polarization means. At this time, the first prism 105 and the second prism 106 are alternately arranged along the row of the light emitting elements 22 (see FIG. 21A), and are configured so that the same polarizing filter is not continuously arranged. Yes. The light emitting unit 103 is arranged in the order of the first prism 105, the second prism 106, the first prism 105,... From the right side when viewed from the front of the image display device 9. The first prism 105 and the second prism 106 are formed in a state where they are separated from each other. However, the first prism 105 and the second prism 106 are not limited to this. , Integral molding).
[0072]
Further, the image display device 9 in the second embodiment includes an observer detection unit that can detect the position of the observer, and a light emission control unit that controls light emission of the light emitting element 22 based on the detected observer position. The observation position of the stereoscopic image can be changed corresponding to the position of the observer. Hereinafter, the configuration will be described in detail.
[0073]
The image display device 9 according to the second embodiment includes a player detection unit 113 as observer detection means. Specifically, the player detection unit 113 is electrically connected to the image display device 9 via a display control device 87 (corresponding to the light emission control means of the present invention) (see FIG. 18). The player detection unit 113 includes a detection CPU 114, a sensor control ROM, a sensor control RAM, a CMOS sensor 115, an amplifier, an A / D converter, an external output terminal, and the like. Note that the game control device 75 and the display control device 87 shown in FIG. 18 have the same configuration as each control device (see FIG. 10) in the first embodiment, and thus detailed description thereof is omitted.
[0074]
The CMOS sensor 115 is a sensor that detects light using a CMOS element, and functions as an imaging unit that captures an image of a player in the front periphery of the gaming machine. In the present embodiment, a 32 × 32 pixel sensor is used.
[0075]
Then, the CMOS sensor 115 has a decorative part in which a ukiyo-e figure is three-dimensionalized in a position near the image display device 9 in the center case 8, for example, in the vicinity of the image display device 9 as shown in FIG. It is attached in a state of protruding forward, and is arranged at a place where the eyes of this decorative part are expressed. Further, the CMOS sensor 115 includes a lens (wide-angle lens) 117 in front, so that an image of the observer (player) can be detected not only in front of the pachinko gaming machine but also in front of the left and right sides. It is configured.
[0076]
As shown in FIG. 20, the CMOS sensor 115 configured in this manner detects imaging in the vicinity of the front of the pachinko gaming machine through a lens in a vertically inverted state. Then, the position corresponding to the player in the detected image becomes dark, and the CMOS sensor 115 reduces the output level of the brightness output from the position corresponding to the player. The imaging data including the brightness data is taken from the CMOS sensor 115 to the detection CPU 114 of the player detection unit 113. Then, the detection CPU 114 calculates an average level of brightness for each dot (pixel) in units of columns, and obtains an average output in the horizontal direction of each column as shown in the figure. Further, the detection CPU 114 of the player detection unit 113 compares the average output in the horizontal direction with a predetermined threshold value, and determines the center of the range that is lower than the threshold value as the position of the player.
[0077]
Note that the player detection unit 113 is not limited to determining the player position by comparing with the threshold value, but relatively compares the average output to determine the range of the player image, and determines the center as the player position. May be. Further, the player image area may be determined by determining the rate of change of the average output and detecting the edge of the player image. Alternatively, the range of the player image may be determined by determining the rate of change of the average output, and the center may be set as the player position.
[0078]
Further, the player detection unit 113 is not limited to the one provided with the CMOS sensor 115. For example, the player detection unit 113 includes a CCD camera or an infrared camera, and detects the player's eye position (pupil position) and the like. May be detected.
[0079]
Next, the control by the display control device 87 for realizing the movement of the observation position capable of stereoscopic viewing will be described based on a flowchart. Here, for convenience of explanation, as shown in FIG. 21A, the arrangement location of the light emitting element 22 on the light emitting substrate 104 is represented by a symbol. Specifically, among the light emitting elements 22 arranged side by side, the symbol A is displayed at the place where the light emitting element 22 that makes the light incident on the first prism 105 (that is, the prism having the polarization unit for the left eye) is disposed. The symbol B is attached to each of the locations where the light emitting elements 22 that allow the light to enter the two prisms 106 (that is, the prism having the right-eye polarization unit), and the numbers are added in ascending order from the right side for each symbol. It is attached with. That is, in the present embodiment, the arrangement location of the light emitting elements 22 is A in order from the right end. ₀ , B ₀ , A ₁ , B ₁ , ... are set. In the light emitting unit 103 of the present embodiment, a total of 56 light emitting elements 22 are arranged, so that A is assigned to each arrangement place. ₀ ~ A ₂₇ , B ₀ ~ B ₂₇ Set the symbol. The subscripts (0 to 27) of the symbols also indicate the numbers of the conversion area pairs 63.
[0080]
First, the control in the case where there is one stereoscopically observable position (when there is only one observer (player)) will be described. In the control of the flowchart shown in FIG. 22, the display control device 87 detects the position of the player by the player detection unit 113 (S1). If the position of the player is detected, the display control device 87 (corresponding to the boundary setting means of the present invention), the range of light emitted from the first polarizing filter (left-eye polarizing unit) 61, and the second polarizing filter A boundary B (see FIG. 21) with the range of light emitted from the (right-eye polarization unit) 62 is set (S2). For example, when an observer (player) is detected on the right side of the pachinko gaming machine, the display control device 87 sets the boundary B on the left side opposite to the liquid crystal display panel 28, and the right side of the pachinko gaming machine. When an observer (player) is detected, a boundary B is set on the right side opposite to the liquid crystal display panel 28. Specifically, the display control device 87 selects the subscript number of the symbol of the arrangement location as the boundary setting value.
[0081]
If the boundary B is set, the display control device 87 causes the light emitting element 22 corresponding to the first prism 105 to emit light on one side (right side) of the boundary B, and corresponds to the second prism 106 on the other side (left side). The light emitting element 22 to be emitted is caused to emit light (S3). Specifically, the display control device 87 sets each light emitting element so that the boundary B between the first polarizing filter 61 and the second polarizing filter 62 is the boundary B in the conversion region pair 63 with the same number as the boundary setting value. 22 is caused to emit or extinguish. That is, the display control device 87 emits light from each light emitting element 22 corresponding to each of the first prism 105 of the conversion area pair 63 including the boundary B and the first prism 105 positioned on the right side of the conversion area pair 63. Each light emitting element 22 corresponding to the second prism 106 on the right side of the conversion area pair 63 including B is extinguished. On the other hand, the display control device 87 causes each of the light emitting elements 22 corresponding to the second prism 106 of the conversion area pair 63 including the boundary B and the second prism 106 located on the left side of the conversion area pair 63 to emit light. Each light emitting element 22 corresponding to the first prism 105 on the left side of the conversion region pair 63 including B is extinguished.
[0082]
For example, if the player detection unit 113 detects that there is a player in front of the pachinko gaming machine, the display control device 87 sets the boundary B to the central conversion area pair 63 with the boundary setting value i = 13. To do. Then, as shown in FIG. ₀ ~ A ₁₃ And B ₁₃ ~ B ₂₇ The light emitting element 22 corresponding to ₀ ~ B ₁₂ And A ₁₄ ~ A ₂₇ The light emitting element 22 corresponding to is extinguished. As a result, light emission similar to the light irradiation shown in FIG. 11 is performed. Therefore, the image display device 9 can display a stereoscopic image so that a player observing in front of the player can stereoscopically view it. The stereoscopic image display principle is the same as that in the first embodiment, and a description thereof will be omitted.
[0083]
Further, if the player detection unit 113 detects that the player has moved and is, for example, on the front right side of the pachinko gaming machine, the display control device 87 sets the boundary setting value to be larger than the median value (i = 13). A value, for example, i = 18 is set, and the boundary B is set to the conversion region pair 63 on the left side of the center. Then, as shown in FIG. ₀ ~ A ₁₈ And B ₁₈ ~ B ₂₇ The light emitting element 22 corresponding to ₀ ~ B ₁₇ And A ₁₉ ~ A ₂₇ The light emitting element 22 corresponding to is extinguished. As a result, light emission similar to the light irradiation shown in FIG. 12 is performed. Therefore, the image display device 9 can display a stereoscopic image so that the player observing on the front right side can view stereoscopically.
[0084]
As described above, the image display device 9 according to the second embodiment can change the emission position of the light converted by the first prism 105 or the second prism 106 by changing the light emission location of the light emitting element 22. Therefore, the position where the stereoscopic image appears can be moved. Thus, the degree of freedom of stereoscopic image display can be expanded over a wide range.
[0085]
Further, even if the player moves, the emission direction of light having different polarization directions can be changed in accordance with the position of the player, and a stereoscopic image can be enjoyed without being restricted by the observation position.
[0086]
Next, control in the case where there are a plurality of stereoscopically observable observation positions (when there are a plurality of observers (players)) will be described. In the control of the flowchart shown in FIG. 23, the display control device 87 detects the positions of a plurality of players by the player detection unit 113 (S11). If the position of the player is detected, the display control device 87 determines the range (width) of light emitted from the first polarizing filter 61 (left-eye polarizing unit) and the second polarizing filter 62 (right-eye polarizing unit). ) Is set (S12). Specifically, it is set how many light-emitting elements 22 emit light for each observation position to enable stereoscopic viewing. For example, in the present embodiment shown in FIG. 24, the light emitting unit 103 includes five or two light emitting elements 22 for each of the first prism 105 and the second prism 106 when three observers are detected. The light is emitted.
[0087]
If the width of the light from each of the polarizing filters 61 and 62 is set, the display control device 87 will emit light from the first polarizing filter 61 (left-eye polarizing unit) corresponding to the detection position of each observer. And a plurality of boundaries B between the range of light emitted from the second polarizing filter 62 (right-eye polarizing unit) (S13). Then, when the display control device 87 causes the light emitting element 22 to emit light to the left and right of the set boundary B, the range of light from the first polarizing filter 61 around one boundary B and the adjacent boundary B Then, it is determined whether or not the range of light from the second polarizing filter 62 around the other boundary B overlaps (S14). As shown in FIG. 24 (a), when light from each of the polarizing filters 61 and 62 overlaps between adjacent boundaries B, an observer who observes a stereoscopic image through light from this location This is because a stereoscopic image may be viewed in a state other than the original stereoscopic state. That is, the light from the first polarizing filter 61 that reaches the right eye reaches the left eye, and the light from the second polarizing filter 62 that reaches the left eye reaches the right eye and jumps out. This is because an image of a wrinkle that gives an effect may be seen as a stereoscopic effect image that is retracted.
[0088]
Therefore, when the display control device 87 determines that the two light ranges are in an overlapping state, the display control device 87 re-uses the light ranges emitted from the polarization filters 61 and 62 as shown in FIG. Set (narrow) (S15). Then, it is determined again whether or not the two light ranges overlap each other (S16). If the two light ranges are not eliminated, the border B adjacent to the adjacent or overlapping state, that is, the observer detection position from the game detection unit is determined. Is deleted to eliminate the overlapped state (S17), and the process returns to step S13.
[0089]
On the other hand, if it is determined in step S14 or S16 that the two light ranges do not overlap, the display control device 87 sets the light emitting element 22 corresponding to the first prism 105 on one side (right side) of the boundary B. On the other side (left side), the light emitting element 22 corresponding to the second prism 106 is caused to emit light with the set width (number of light emitting elements 22) (S18), and the process returns to step S11 to detect the observer again. If there is a change in the position of the observer, the light emission point of the light emitting element 22 can be moved to move the observation position where stereoscopic viewing is possible (see FIG. 24C).
[0090]
In this way, the image display device 9 can increase the number of light emitting portions of the light emitting element 22 in accordance with the position of the observer, expands the degree of freedom of stereoscopic image display over a wide range, and is not restricted by the number of observers. An image can be displayed so that a plurality of observers can view stereoscopically. In addition, the observer-following image display device 9 can be realized with a compact configuration without using a large-scale device.
[0091]
By the way, in the above-described second embodiment, the light emitting unit 103 is provided with the light emitting elements 22 arranged in a line, and the first prisms 105 or the second prisms 106 are alternately arranged for each light emitting element 22. However, the present invention is not limited to this. For example, in the third embodiment shown in FIGS. 25 and 26, the light emitting unit 103 of the image display device 9 is basically the same as that of the second embodiment, but the arrangement state of the light emitting elements 22 is different.
[0092]
That is, in the light emitting unit 103, as shown in FIG. 25A, a plurality of light emitting elements 22 are arranged on the light emitting substrate 104 to form a first light emitting element array 121 and a second light emitting element array 122. The first light emitting element row 121 and the second light emitting element row 122 are arranged in parallel to each other along the longitudinal direction of the light emitting substrate 104. Note that the light emitting substrate 104 of the present embodiment is curved in a state along the virtual arc line A (see FIG. 6) in which the optical path lengths to the center of the Fresnel lens 25 are equidistant, as in the second embodiment. is doing. Therefore, both light emitting element rows 121 and 122 are also formed on a virtual arc line. The light emitting unit 103 includes a first prism 105 for each light emitting element 22 constituting the first light emitting element row 121 and a second prism 106 for each light emitting element 22 constituting the second light emitting element row 122. . As in the second embodiment, the first prism 105 includes the first polarizing filter 61 on the exit surface 111, and the second prism 106 includes the second polarizing filter 62 on the exit surface 111. Therefore, in the light emitting unit 103, the first polarizing filter 61 row and the second polarizing filter 62 row are arranged in parallel to each other along the longitudinal direction of the light emitting unit 103.
[0093]
When the light emitting element 22 row is configured as described above and the light emission control is performed based on the flowcharts shown in FIGS. 22 and 23, the light emitting unit 103 corresponds to the second polarizing filter 62 as shown in FIGS. The light emitting element 22 to be emitted can be emitted with a predetermined width from the first polarizing filter 61 without being placed in a state where the light emitting element 22 is turned off, and the light emitting element corresponding to the first polarizing filter 61 The light can be emitted from the second polarizing filter 62 with a predetermined width without being arranged in the state where the light is turned off. Therefore, the light converted by the polarizing filters 61 and 62 can be concentrated and irradiated with bright light, so that a stereoscopic image can be clearly displayed.
[0094]
In the light emitting unit 103 of the second and third embodiments, the light emitting elements 22 are arranged on the curved light emitting substrate 104 and configured in a curved shape. However, the present invention is not limited to this, and the light emitting substrate is similar to the first embodiment. 104 may be formed in a polygonal line, and the light emitting element 22 may be arranged in a polygonal line on the light emitting substrate 104. Further, the light emitting unit 103 is suitable for displaying a flat image in a demonstration display before and after the start of the game, and if all the light emitting elements 22 emit light, an image can be displayed brighter than the stereoscopic image display. is there.
[0095]
Moreover, although the display control apparatus 87 of the above-mentioned 2nd and 3rd embodiment performed light emission control of the light emitting element 22 based on the detection result of the player detection unit 113, it is not restricted to this. For example, if a display adjustment device operated by the player himself / herself is provided so that the light emitting point of the light emitting element 22 can be moved, the position where the stereoscopic view is possible can be adjusted according to the player's own posture, It is preferable that the image display device 9 can be adjusted so that a friend or the like who is playing a game intentionally shows a stereoscopic image.
[0096]
The above-described embodiment has been described by taking a pachinko gaming machine as a typical gaming machine as an example. However, the present invention is not limited to this, and if an image display device capable of displaying a stereoscopic image is provided, for example, an internal It may be a gaming machine such as a sealed ball type pachinko machine, an arrangement ball type game machine, or a sparrow ball type game machine that circulates a game ball enclosed in the box.
[0097]
It should be understood that the above-described embodiment is illustrative in all respects and not restrictive. The present invention is not limited to the above description, but is defined by the scope of the claims, and includes all modifications within the scope and meaning equivalent to the scope of the claims.
[0098]
【The invention's effect】
As described above, the present invention has the following effects.
That is, according to the first aspect of the present invention, the linear light source is disposed in the left-right direction with respect to the liquid crystal display panel, and the light emitting portion is positioned at an approximately equal distance from the center of the optical means. The polarization means is configured to convert light from the linear light source into light of the specific polarization direction, and light from the linear light source. A second conversion region that converts light having a polarization direction orthogonal to the specific polarization direction is adjacent to each other to form a conversion region pair, and the first conversion region and the second conversion region are the length of the linear light source. Since a plurality of the conversion region pairs are provided in a state of being alternately arranged along the direction, an image display device capable of observing a stereoscopic image from a plurality of observation positions with a simple configuration can be realized.
[0099]
According to a second aspect of the present invention, the linear light-emitting source includes a plurality of point-like light-emitting elements arranged in a line, and a prism that increases the luminous intensity by narrowing the irradiation range of the point-like light-emitting elements. Provided for each point light emitting element, the polarizing means is formed on a translucent plate that is long in the same direction as the linear light emitting source, a first polarizing filter constituting the first conversion region, and the second conversion region. The conversion region pair is configured by adjoining the second polarizing filter that constitutes the state, and the first polarizing filter and the second polarizing filter are alternately arranged along the longitudinal direction of the linear light emitting source Thus, since a plurality of the conversion area pairs are provided, an image display device that can be stereoscopically viewed from a plurality of observation positions can be realized with a simpler structure that facilitates the manufacture of the polarizing means.
[0100]
According to a third aspect of the present invention, the linear light-emitting source includes a plurality of point-like light emitting elements arranged in a line, and a prism that increases the luminous intensity by narrowing the irradiation range of the point light-emitting elements. The prism is provided for each point light emitting element, and the prism includes an incident surface on which light from the point light emitting element is incident, and an emission surface that emits light that has been incident from the incident surface and whose optical path is corrected. A prism block is formed by connecting a plurality of the prisms, and the polarizing means has the first conversion region and the second conversion region adjacent to each other along the longitudinal direction of the linear light source on the exit surface of the prism block. Forming the conversion area pairs to form, by arranging a plurality of the prism blocks in a state where the first conversion areas and the second conversion areas are alternately arranged, the plurality of conversion area pairs are provided, 3D image display from multiple observation positions The apparatus can be realized with a simple configuration that facilitates positioning of the polarization means.
[0101]
According to a fourth aspect of the present invention, the linear light-emitting source is composed of a plurality of point-like light emitting elements arranged in a line, and the first luminous intensity is increased by narrowing the irradiation range of the point light-emitting elements. A prism or a second prism is provided for each point light emitting element, and the first prism and the second prism have an incident surface on which light from the point light emitting element is incident, and an optical path corrected by being incident from the incident surface. An output surface for emitting light, and the polarizing means forms the first conversion region on the output surface of the first prism, forms the second conversion region on the output surface of the second prism, A pair of one prism and a second prism constitutes the conversion area pair, and a plurality of the conversion area pairs are provided in a state where the first prism and the second prism are alternately arranged, and the point light emitting element Because it has a light emission control means to control the light emission of Emission position of the converted light in the first conversion area or the second conversion area by changing or increasing the light emitting portions of Jo-emitting element can be changing or increasing. Therefore, the position where the stereoscopic image appears can be increased or moved. Accordingly, it is possible to provide an image display apparatus that can easily deal with the number of observers and observation positions by expanding the degree of freedom of stereoscopic image display over a wide range.
[0102]
According to a fifth aspect of the present invention, the linear light emitting source is disposed in the left-right direction with respect to the liquid crystal display panel, and the first light emitting element array and the second light emitting element are arranged by arranging a plurality of point light emitting elements. An element row is formed, and each light emitting element row is arranged in parallel to each other and is configured in a curved line or a broken line shape in a state of being located at an approximately equal distance from the center of the optical means, and the first light emitting element row includes The first light emitting element array is provided with a first prism for narrowing the irradiation range of the point light emitting elements for increasing the luminous intensity for each point light emitting element array, and the second light emitting element array has a light intensity by reducing the irradiation range of the point light emitting elements. A second prism to be raised is provided for each point light emitting element array, and the first prism and the second prism have an incident surface on which light from the point light emitting element is incident, and an optical path corrected by being incident from the incident surface. An exit surface for emitting light, and the polarizing means includes A first conversion region for converting light whose polarization direction is not specified into light of the specific polarization direction on an emission surface of one prism, and light whose polarization direction is not specified on the emission surface of the second prism; A second conversion region that converts light into a polarization direction orthogonal to the specific polarization direction, wherein the first conversion region and the second conversion region are arranged in parallel along a longitudinal direction of the linear light-emitting source; Since the light emission control means for controlling the light emission of the point light emitting element is provided, the point light emitting element corresponding to the other conversion area is turned off without being disposed between the conversion areas. Light can be emitted with a predetermined width. Therefore, it is possible to concentrate the light converted by each conversion area and irradiate bright light to display a stereoscopic image clearly.
[0103]
According to the invention described in claim 6, the light emission control means includes a range in which light having a specific polarization direction is emitted from the polarization means, and a range in which light having a polarization direction orthogonal to the specific polarization direction is emitted. A boundary setting means for setting the boundary of the light source, and a point light emitting element corresponding to the first prism emits light on one side of the boundary and a point light emitting element corresponding to the second prism emits light on the other side. It is possible to move the boundary between the range in which the light having the polarization direction is emitted and the range in which the light having the polarization direction orthogonal to the specific polarization direction is emitted, and to change the stereoscopically observable observation position. Therefore, the image can be displayed so that the observer can view stereoscopically without being restricted by the display position of the image.
[0104]
According to a seventh aspect of the present invention, there is provided an observer detection means capable of detecting the position of the observer, and the light emission control means is a point light emitting element based on the detection result of the observer position by the observer detection means. Therefore, the point light emitting elements corresponding to the first conversion region or the second conversion region can be made to emit light corresponding to the position of the observer. Therefore, even when the observer moves, light of two types of polarization directions can be transmitted through the image so that stereoscopic viewing can be suitably performed from the moving position. In addition, when there are a plurality of observers, the position of each observer can be detected, and the point light emitting element can be caused to emit light corresponding to the position of each observer, which is restricted by the number of observers. And an image can be displayed so that a plurality of observers can view stereoscopically.
[0105]
According to the invention described in claim 8, the variable display device is provided in which the variable display game for variably displaying the identification information is executed, and the identification information displayed as a result mode of the variable display game is a specific display mode. A game machine that gives a predetermined game value in the event that the variable display device is configured using the image display device according to any one of claims 1 to 7, so that the player Even if the posture is lost, the stereoscopic image can be seen. Therefore, the player can prevent the interest of the game by the stereoscopic image from being impaired even in a relaxed posture. And when enjoying a game with a game machine adjacent to a friend etc., the image of each other's game machine can be stereoscopically viewed from the next position, and the interest of the game can be shared.
In addition, it is possible to provide the gaming machine with an observer-following image display device in a state where the observer-following image display device is suppressed in a compact configuration as compared with the related art. Therefore, even if the gaming machine installation space of the island facility (gaming machine installation facility) is limited, it is possible to install the gaming machine without hindering the image display device.
[Brief description of the drawings]
FIG. 1 is a front view of a game board of a pachinko gaming machine.
FIG. 2 is a perspective view of an image display device.
FIG. 3 is an exploded perspective view of the image display device.
FIG. 4 is a configuration diagram of an optical system of the image display apparatus.
FIG. 5 is an exploded perspective view seen from the rear of the light emitting unit.
FIG. 6 is a relationship diagram between the center of a Fresnel lens and a light emitting substrate.
FIG. 7 is a cross-sectional view of a light emitting unit.
8A is an enlarged cross-sectional view of a light emitting unit, and FIG. 8B is a side view of a prism.
9A is an enlarged view of the boundary between the first polarizing filter and the second polarizing filter, FIG. 9B is a plan view of the polarizing filter, and FIG. 9C is a graph showing a difference in polarization direction between right and left using a retardation film. It is a block diagram of the made polarizing filter.
FIG. 10 is a block configuration diagram of a control system of a pachinko gaming machine.
FIG. 11 is a plan view of an optical system of the image display device, and is a schematic view showing light from a central light emitting element array.
FIG. 12 is a plan view of an optical system of the image display device, and is a schematic view showing light from the left side light emitting element array.
FIG. 13 is a plan view of an optical system of the image display device, and is a schematic diagram showing light from a right light emitting element array.
FIG. 14 is an explanatory diagram of an appearance position of a stereoscopic image in the image display device, (a) is an explanatory diagram of an appearance position on the display surface, (b) is an explanatory diagram of an appearance position ahead of the display surface, c) is an explanatory diagram of an appearance position behind the display surface.
FIG. 15 is an exploded perspective view seen from the rear of a light emitting unit in which a polarizing filter is provided on the exit surface of the prism row.
16A and 16B are schematic views of a light emitting unit according to a second embodiment, where FIG. 16A is a plan view and FIG. 16B is a front view.
FIG. 17 is a perspective view of a first prism and a second prism.
FIG. 18 is a block configuration diagram of a player detection unit in the control system of the pachinko gaming machine.
FIG. 19 is a front view of a center case provided with a player detection unit.
FIG. 20 is an explanatory diagram showing the principle of the player detection unit.
FIG. 21A is a diagram showing the arrangement of the first prism and the second prism, FIG. 21B is an explanatory diagram showing light emission when the boundary is set at the center, and FIG. 21C is the boundary on the left side. It is explanatory drawing which shows light emission when set.
FIG. 22 is a flowchart of light emission control in the case where there is one observation position where stereoscopic viewing is possible.
FIG. 23 is a flowchart of light emission control when there are a plurality of stereoscopically observable observation positions.
24A is an explanatory diagram showing light emission when a plurality of boundaries are set, FIG. 24B is an explanatory diagram showing light emission after adjusting the width of the light emission part from the state of FIG. ) Is an explanatory view showing light emission in a state where the light emission portion in the state of (b) is moved.
FIG. 25A is a schematic diagram for explaining light emission of a light emitting unit provided with a first light emitting element row and a second light emitting element row, and FIG. 25B is an explanatory diagram showing light emission when a boundary is set at the center. (C) is explanatory drawing which shows light emission when the boundary is set on the left side.
26A is an explanatory diagram showing light emission when a plurality of boundaries are set in a light emitting unit provided with a first light emitting element row and a second light emitting element row, and FIG. 26B is a state of FIG. (C) is explanatory drawing which shows light emission of the state which moved the light emission location of the state of (b).
[Explanation of symbols]
1 Game board
2 Game board body
5 Guide rail
6 game area partition members
7 Game area
8 Center case
9 Image display device
10 start prize opening
11 Special Variable Prize Winner
12 General prizes
13 Windmill
14 Lamps / LEDs
15 Out mouth
17 Opening window
18 Mounting board
19 Armor
20 housing
20a wall
21 Display section
22 Light emitting element
22L Left side light emitting element row
22C Central light-emitting element array
22R Right side light emitting element row
23 Light-emitting unit
24 Reflector
25 Fresnel lens
26 Polarizing filter
27 Light source
28 LCD panel
31 Rear case
32 Front frame
33 Front cover
34 opening
35 Diffuser
36 Display holding frame
39 Fine retardation plate
39a first region
39b second region
40 First Polarizing Sheet
41 Second polarizing sheet
43 Lens holder
45 Light Emitting Unit Case
45a Case lid
45b Case body
46 Light Emitting Board
48 prism rows
48L Left prism row
48C Central prism row
48R Right side prism row
49 Filter holding frame
52 Flat part
53 Prism
54 Outgoing surface
55 Incident surface
60 base film
61 First polarizing filter
62 Second polarizing filter
63 Transformation domain pairs
63L left side conversion area pair
63C Central transformation region pair
63R right side conversion area pair
64 Polarizing film
65 retardation film
68 Air intake
69 Exhaust vent
70 Air intake slit
71 Exhaust fan
72 Duct
75 Game control device
76 Microcomputer for game
77 Input interface
78 Output interface
79 Terminal for external communication
81 General prize opening sensor
82 Special design start sensor
83 Normal pattern start sensor
84 count sensor
85 Continuity sensor
87 Display controller
88 Emission control device
89 Ordinary electric accessory solenoid
90 Grand Prize Solenoid
91 Card unit
92 Decoration control device
93 Sound control device
94 CPU for display control
95 GDP
96 Composite conversion device
97 prism row
97L Left prism row
97C Central prism row
97R Right prism row
98 Outgoing surface
103 Light emitting unit
104 Light emitting substrate
105 1st prism
106 2nd prism
107 Light Emitting Unit Case
108 Cover film
109 Filter holding frame
110 Incident surface
111 Output surface
113 Player detection unit
114 CPU for detection
115 CMOS sensor
116 decoration
117 lens
121 1st light emitting element row | line | column
122 Second light emitting element array

Claims (8)

A liquid crystal display panel capable of transmitting the light irradiated from the back;
A light source that irradiates the liquid crystal display panel with light having a specific polarization direction and light having a polarization direction orthogonal to the specific polarization direction;
A first region disposed between the liquid crystal display panel and the light source and transmitting light of the specific polarization direction; and a second region transmitting light of a polarization direction orthogonal to the specific polarization direction, A filter provided repeatedly in the vertical direction,
The light source includes a linear light emitting source that emits light whose polarization direction is not specified, light that is not specified in polarization direction, light in the specific polarization direction, and light in a polarization direction orthogonal to the specific polarization direction. In an image display device configured to include: a polarizing unit that converts and outputs light; and an optical unit that refracts light in different polarization directions in a direction that reaches the left and right eyes and irradiates the liquid crystal display panel.
The linear light source is arranged in the left-right direction with respect to the liquid crystal display panel, and the light emitting part is configured in a curved line or a broken line in a state of being located at an approximately equal distance from the center of the optical means,
The polarization means includes a first conversion region that converts light from the linear light source into light having the specific polarization direction, and light having a polarization direction orthogonal to the specific polarization direction. A second conversion region that converts light is adjacent to each other to form a conversion region pair,
An image display device comprising a plurality of pairs of conversion areas in a state where the first conversion areas and the second conversion areas are alternately arranged along the longitudinal direction of the linear light emitting source. The linear light-emitting source includes a plurality of point-like light emitting elements arranged in a line, and includes a prism for each point light-emitting element that increases the luminous intensity by narrowing the irradiation range of the point light-emitting elements.
The polarizing means includes a first polarizing filter that constitutes the first conversion region and a second polarizing filter that constitutes the second conversion region on a translucent plate that is long in the same direction as the linear light source. Are formed side by side to form the transformation region pair,
The said 1st polarizing filter and the said 2nd polarizing filter were equipped with two or more said conversion area | region pairs in the state which was located in a line along the longitudinal direction of the said linear light-emitting source. Image display device. The linear light-emitting source includes a plurality of point-like light emitting elements arranged in a line, and includes a prism for each point light-emitting element that increases the luminous intensity by narrowing the irradiation range of the point light-emitting elements.
The prism includes an incident surface on which light from a point light emitting element is incident, and an emission surface that emits light that has been incident from the incident surface and whose optical path is corrected,
A prism block is configured by connecting a plurality of the prisms,
The polarizing means forms the conversion area pair by forming the first conversion area and the second conversion area adjacent to each other along the longitudinal direction of the linear light source on the exit surface of the prism block,
2. The image display according to claim 1, wherein a plurality of the conversion area pairs are provided by arranging a plurality of the prism blocks in a state where the first conversion areas and the second conversion areas are alternately arranged. apparatus. The linear light emitting source is composed of a plurality of point light emitting elements arranged in a line, and the first prism or the second prism that increases the luminous intensity by narrowing the irradiation range of the point light emitting elements is provided for each point light emitting element. In preparation for
The first prism and the second prism each include an incident surface on which light from a point light emitting element is incident, and an output surface that emits light having an optical path corrected by entering from the incident surface,
The polarizing means forms the first conversion region on the exit surface of the first prism, forms the second conversion region on the exit surface of the second prism, and pairs the first prism and the second prism. By configuring the conversion area pair, a plurality of the conversion area pairs in a state where the first prism and the second prism are alternately arranged,
The image display apparatus according to claim 1, further comprising a light emission control unit that controls light emission of the point light emitting element. A liquid crystal display panel capable of transmitting the light irradiated from the back;
A light source that irradiates the liquid crystal display panel with light having a specific polarization direction and light having a polarization direction orthogonal to the specific polarization direction;
A first region disposed between the liquid crystal display panel and the light source and transmitting light of the specific polarization direction; and a second region transmitting light of a polarization direction orthogonal to the specific polarization direction, A filter provided repeatedly in the vertical direction,
The light source includes a linear light emitting source that emits light whose polarization direction is not specified, light that is not specified in polarization direction, light in the specific polarization direction, and light in a polarization direction orthogonal to the specific polarization direction. In an image display device configured to include: a polarizing unit that converts and outputs light; and an optical unit that refracts light in different polarization directions in a direction that reaches the left and right eyes and irradiates the liquid crystal display panel.
The linear light-emitting source is arranged in the left-right direction with respect to the liquid crystal display panel, and a plurality of point-like light-emitting elements are arranged to form a first light-emitting element array and a second light-emitting element array, , Arranged in parallel with each other, and configured in a curved line or a broken line in a state of being located at an approximately equal distance from the center of the optical means
The first light emitting element row includes a first prism for each point light emitting element row that increases the luminous intensity by narrowing the irradiation range of the point light emitting elements.
The second light emitting element array includes a second prism for each point light emitting element array that increases the luminous intensity by narrowing the irradiation range of the point light emitting elements,
The first prism and the second prism each include an incident surface on which light from a point light emitting element is incident, and an output surface that emits light having an optical path corrected by entering from the incident surface,
The polarizing means includes a first conversion region for converting light whose polarization direction is not specified into light of the specific polarization direction on the exit surface of the first prism, and the exit surface of the second prism includes the A second conversion region that converts light whose polarization direction is not specified into light having a polarization direction orthogonal to the specific polarization direction; and the first conversion region and the second conversion region are arranged in the longitudinal direction of the linear light emitting source. In parallel along the direction,
An image display device comprising light emission control means for controlling light emission of the point light emitting element. The light emission control unit includes a boundary setting unit that sets a boundary between a range in which light with a specific polarization direction is emitted from the polarization unit and a range in which light with a polarization direction orthogonal to the specific polarization direction is emitted,
6. The point light emitting element corresponding to the first prism is caused to emit light on one side of the boundary, and the point light emitting element corresponding to the second prism is caused to emit light on the other side. Image display device. Equipped with an observer detection means capable of detecting the position of the observer;
The image display device according to claim 4, wherein the light emission control unit controls light emission of the point light emitting element based on a detection result of an observer position by the observer detection unit. . A game that includes a variable display device that executes a variable display game for variably displaying identification information, and that gives a predetermined game value when the identification information displayed as a result mode of the variable display game is in a specific display mode Machine,
A gaming machine comprising the variable display device using the image display device according to any one of claims 1 to 7.

Images