JP4139235B2 - Image display device and game machine equipped with image display device - Google Patents

Description

[0001]
[Technical field to which the invention belongs]
The present invention relates to an image display device, and more particularly to a three-dimensional image display device that allows an observer to stereoscopically view without wearing special glasses.
[0002]
[Prior art]
Conventional three-dimensional image display devices have a right-eye polarization filter section and a left-eye polarization filter section whose polarization directions are orthogonal to the front left and right of the light source, and each light passing through each filter section is parallelized by a Fresnel lens. The liquid crystal display element is irradiated as light, and the polarizing filters on both sides of the liquid crystal display element are alternately arranged with linear polarizing filter line portions orthogonal to each other for each horizontal line, and the light source side and the observation side are opposed to each other. The linear polarization filter line section to be orthogonalized has the orthogonal polarization direction, and the liquid crystal panel of the liquid crystal display element alternates video information for the right eye and left eye for each horizontal line according to the light transmission lines of the two polarization filters. It was the composition which is displayed in. In addition, linear polarization filter line portions orthogonal to each other are arranged alternately for each horizontal line in the light source side polarization filter, and the observation side polarization filter is linearly polarized light having one linear polarization filter line portion of the light source side polarization filter. As a filter, the liquid crystal panel of the liquid crystal display element is configured to alternately display video information for the right eye and the left eye for each horizontal line in accordance with the light transmission line of the polarizing filter on the light source side (for example, (See Patent Document 1).
[0003]
In addition, when a game ball wins at a predetermined winning opening, numbers, symbols, patterns, etc. are variably displayed on a drum or display arranged almost in the center of the pachinko game board, and the same numbers etc. are stopped together. In some cases, the player wins a predetermined number of prize balls. The image displayed on the display that performs this variable display or the like is a planar two-dimensional image, but in order to further enhance the display effect, an image corresponding to the left and right eyes using a lenticular lens having sharp directivity. A gaming machine that provides information and displays a planar image as a stereoscopic image has been proposed (see, for example, Patent Document 2).
[0004]
[Patent Document 1]
JP-A-10-63199
[Patent Document 2]
Japanese Patent Laid-Open No. 7-31729
[0005]
[Problems to be solved by the invention]
However, in the above-described conventional image display device, the liquid crystal display element is irradiated to accurately irradiate the liquid crystal display element with the light transmitted through the linear polarization filter line portions having the polarization characteristics orthogonal to each other for each horizontal line. Therefore, when the observer moves up and down, the light cannot reach the eyes of the observer, and the observer cannot see the image clearly.
[0006]
The present invention relates to a three-dimensional image display device that allows an observer to stereoscopically view without wearing special glasses, and an image that can obtain a bright and clear image even when the position where the observer views the image moves up and down. An object is to provide a display device.
[0007]
[Means for Solving the Problems]
  The first invention includes a liquid crystal display panel capable of transmitting light irradiated from behind, a first light having a specific polarization, and a second light having a polarization axis orthogonal to the first light. A light source that irradiates the liquid crystal display panel; optical means that refracts light emitted from the light source in a direction that reaches each of the left and right eyes; and the liquid crystal display panel and the light source, A striped filter in which a first region that transmits the second light and a second region that transmits the second light are repeatedly provided in a fixed direction, and whether the liquid crystal display panel is energized or not energized And a polarizing plate having a polarization characteristic that blocks light transmitted through the liquid crystal display panel, wherein the striped filter has a horizontal direction in which the first region and the second region are in a horizontal direction. And the light source is the first light source. Of a first light source for emitting light polarized light and a second light source for generating light of the second polarization, the liquid crystaldisplayIndividually arranged at symmetrical positions from substantially the center of the panel, the optical means,The optical means is individually provided corresponding to each light source between the first light source and the liquid crystal display panel and between the second light source and the liquid crystal display panel.The light generated from the first light source and the second light source isOne of the optical means isOneAboveLight from light sourceThroughLeft eyeWhile refracting to reach,The other optical means comprises:The otherAboveLight from light sourceThroughTo reach the right eyeInIt is characterized by being refracted.
[0008]
  According to a second invention, in the first invention, the first light source and the second light source have a vertically long shape.
[0011]
  First3The invention of the firstOr secondIn the invention, the first light source and the second light source are characterized by individually arranging light emitting elements that generate light of three primary colors.
[0013]
  First4The invention includes an image display device provided with a display area in which a plurality of pieces of identification information are variably displayed, and variability display control means for controlling variability display of the identification information, and the identification information displayed on the image display device is displayed. In a gaming machine capable of performing a variable display game for variable display and generating a special game state that gives a specific game value in relation to a result mode of the variable display game, the image display device is irradiated from behind A liquid crystal display panel capable of transmitting light; a first light that is a specific polarization; a light source that irradiates the liquid crystal display panel with a second light whose polarization axis is orthogonal to the first light; An optical means for refracting light emitted from a light source in a direction reaching each of the left and right eyes; a first region disposed between the liquid crystal display panel and the light source; and transmitting the first light; The second region that transmits the second light And a striped filter provided repeatedly in a certain direction, and a polarizing plate having a polarization characteristic that blocks light transmitted through the liquid crystal display panel when the liquid crystal display panel is energized or not energized, and , Be preparede,The striped filter is formed by repeatedly providing the first region and the second region in the horizontal direction, and the light source includes a first light source that generates the first polarized light, and the second light source. A second light source that generates polarized light;displayIndividually arranged at symmetrical positions from substantially the center of the panel, the optical means,Between the first light source and the liquid crystal display panel, and between the second light source and the liquid crystal display panel, each provided individually corresponding to each light source,The light generated from the first light source and the second light source isOne of the optical means isOneAboveLight from light sourceThroughLeft eyeWhile refracting to reach,The other optical means comprises:The otherAboveLight from light sourceThroughTo reach the right eyeInIt is characterized by being refracted.
[0015]
Operation and effect of the invention
  In the first invention, a liquid crystal display panel capable of transmitting light irradiated from the rear, the first light having a specific polarization, and the second light having a polarization axis orthogonal to the first light, A light source that irradiates the liquid crystal display panel; optical means that refracts light emitted from the light source in a direction that reaches each of the left and right eyes; and the liquid crystal display panel and the light source, A striped filter in which a first region that transmits the second light and a second region that transmits the second light are repeatedly provided in a fixed direction, and whether the liquid crystal display panel is energized or not energized And a polarizing plate having a polarization characteristic that blocks light transmitted through the liquid crystal display panel, wherein the striped filter has a horizontal direction in which the first region and the second region are in a horizontal direction. The light source is provided repeatedly. A first light source for generating light of first polarization and a second light source for generating light of the second polarization, the liquid crystaldisplayIndividually arranged at symmetrical positions from substantially the center of the panel, the optical means,Between the first light source and the liquid crystal display panel, and between the second light source and the liquid crystal display panel, each provided individually corresponding to each light source,The light generated from the first light source and the second light source isOne of the optical means isOneAboveLight from light sourceThroughLeft eyeWhile refracting to reach,The other optical means comprises:The otherAboveLight from light sourceThroughTo reach the right eyeInSince the image is refracted, a bright and clear image can be obtained even if the observer moves the image viewing position up and down.Further, the emission direction of light emitted from the light source can be finely adjusted for each of the left and right light sources.
[0016]
In the second invention, since the first light source and the second light source have a vertically long shape, it is possible to effectively use the vertical direction of the casing by efficiently arranging the light sources for the height of the casing. And the brightness of the light source can be sufficiently secured.
[0019]
  First3In the invention, since the first light source and the second light source are individually arranged with light emitting elements that generate light of the three primary colors, light sources of different colors having different refractive indexes are efficiently arranged so that the left and right eyes of the observer Can be configured to reach.
[0021]
  First4In the invention, the image display device provided with a display area for variably displaying a plurality of identification information, and the variation display control means for controlling the variation display of the identification information, the identification information displayed on the image display device is provided. In a gaming machine capable of performing a variable display game for variable display and generating a special game state that gives a specific game value in relation to a result mode of the variable display game, the image display device is irradiated from behind A liquid crystal display panel capable of transmitting light; a first light that is a specific polarization; a light source that irradiates the liquid crystal display panel with a second light whose polarization axis is orthogonal to the first light; An optical means for refracting light emitted from a light source in a direction reaching each of the left and right eyes; a first region disposed between the liquid crystal display panel and the light source; and transmitting the first light; Second to transmit second light And a polarizing plate having a polarization characteristic that blocks light transmitted through the liquid crystal display panel when the liquid crystal display panel is energized or not energized. And be preparede,The striped filter is formed by repeatedly providing the first region and the second region in the horizontal direction, and the light source includes a first light source that generates the first polarized light, and the second light source. A second light source that generates polarized light;displayIndividually arranged at symmetrical positions from substantially the center of the panel, the optical means,Between the first light source and the liquid crystal display panel, and between the second light source and the liquid crystal display panel, each provided individually corresponding to each light source,The light generated from the first light source and the second light source isOne of the optical means isOneAboveLight from light sourceThroughLeft eyeWhile refracting to reach,The other optical means comprises:The otherAboveLight from light sourceThroughTo reach the right eyeInSince the light source is refracted, the vertical direction of the image display device can be used effectively by efficiently arranging the light source for the height of the image display device, and the brightness of the light source can be sufficiently secured.Further, the emission direction of light emitted from the light source can be finely adjusted for each of the left and right light sources.
[0023]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0024]
FIG. 1 is an explanatory diagram showing the configuration of the image display apparatus according to the first embodiment of the present invention.
[0025]
The light source 801a includes a light emitting element 810a and a polarizing filter 811a, and the light source 801b includes a light emitting element 810b and a polarizing filter 811b. The light source 801a and the light source 801b are provided at symmetrical positions from a substantially central portion of the liquid crystal display panel 804. The light emitting elements 810a and 810b are configured by arranging linear light sources such as cold cathode tubes vertically or by arranging dot light sources such as white light emitting diodes vertically. The polarization characteristics of the polarization filter 811a and the polarization filter 811b are set so that the polarization of the transmitted light is different from each other (for example, the polarization of the light transmitted by the polarization filter 811a and the polarization filter 811b is shifted by 90 degrees). ing.
[0026]
The Fresnel lens 812 has a lens surface having concentric concavities and convexities on one side surface, and is provided in the vicinity of the fine retardation plate 802 substantially in parallel with the fine retardation plate 802 and functions as an optical means.
[0027]
The light emitted from the light-emitting element 810a is transmitted only through the polarization filter 811a with a certain amount of polarized light, and the light emitted from the light-emitting element 810b is transmitted through the polarization filter 811b with a certain polarization different from that of the light-emitting element 810a. Only light is transmitted. That is, the light emitting elements 810a and 810b and the polarization filters 811a and 811b constitute light sources 801a and 801b that generate light of specific different polarizations. As will be described later, the light that has passed through the polarizing filter 811a reaches the left eye of the observer, and the light that has passed through the polarizing filter 811b reaches the right eye of the observer.
[0028]
Lights of different polarizations emitted from the light source 801a and the light source 801b are applied to the Fresnel lens 812. The Fresnel lens 812 is a convex lens, and the Fresnel lens 812 refracts the optical path of light emitted so as to diffuse from the light emitting element 10 to be substantially parallel, transmits the fine retardation plate 802, and irradiates the liquid crystal display panel 804. .
[0029]
At this time, light emitted from the fine retardation plate 802 is emitted so as not to spread in the left-right direction and is applied to the liquid crystal display panel 804. That is, light that has passed through a specific region of the fine retardation plate passes through a specific display unit portion of the liquid crystal display panel 804.
[0030]
Of the light irradiated to the liquid crystal display panel 804, the light that has passed through the polarizing filter 811a and the light that has passed through the polarizing filter 811b are incident on the Fresnel lens 812 at different angles, and are refracted by the Fresnel lens 812 to be liquid crystal. The light is emitted from the display panel 804 in different directions in the left and right directions.
[0031]
The liquid crystal display panel 804 has a liquid crystal that is twisted and aligned at a predetermined angle (for example, 90 degrees) between two transparent plates (for example, glass plates). It is composed. The light incident on the liquid crystal display panel is emitted with the polarization of the incident light shifted by 90 degrees in a state where no voltage is applied to the liquid crystal. On the other hand, in a state where a voltage is applied to the liquid crystal, the twist of the liquid crystal can be solved, so that incident light is emitted as it is with polarized light.
[0032]
A fine retardation plate 2 and a polarizing plate 803 (first polarizing plate) are disposed on the light source 1 side of the liquid crystal display panel 804, and a polarizing plate 805 (second polarizing plate) is disposed on the viewer side. ing.
[0033]
In the fine phase difference plate 802, regions for changing the phase of transmitted light are repeatedly arranged at fine intervals. Specifically, a light-transmitting base material 822 has a fine region 802a where a half-wave plate 821 having a minute width is provided and a region 802b where the half-wave plate 821 is not provided. It is repeatedly provided at regular intervals. That is, a region 802a that changes the phase of light transmitted by the provided half-wave plate 821 and a region 802b that does not change the phase of light transmitted because the half-wave plate 821 is not provided are fine. It is provided repeatedly at intervals. The half-wave plate 821 functions as a phase difference plate that changes the phase of transmitted light.
[0034]
The half-wave plate 821 is arranged so that its optical axis is inclined 45 degrees with respect to the polarization axis of the light transmitted through the polarization filter 811a, and the polarization axis of the light transmitted through the polarization filter 811a is rotated by 90 degrees and emitted. That is, the polarization axis of the light transmitted through the polarizing filter 811a is rotated by 90 degrees so as to be equal to the polarization of the light transmitted through the polarizing filter 811b. That is, the region 802b where the half-wave plate 821 is not provided transmits light having the same polarization as the polarizing plate 803 that has passed through the polarizing filter 811b, and the region 2a where the half-wave plate 821 is provided The light having passed through the polarizing filter 811a and whose polarizing axis is orthogonal to the polarizing plate 803 is rotated so as to be equal to the polarizing axis of the polarizing plate 803 and is emitted.
[0035]
The repetition of the polarization characteristics of the fine phase difference plate 802 is different in the polarization of light transmitted for each display unit (that is, for each vertical line of the display unit) at substantially the same pitch as the display unit of the liquid crystal display panel 804. Like that. Therefore, the polarization characteristics of the fine phase difference plate 802 corresponding to each vertical line (scanning line) of the display unit of the liquid crystal display panel 804 are different, and the direction of the emitted light is different for each vertical line.
[0036]
Alternatively, the polarization characteristic of the fine retardation plate 802 is repeated as an integer multiple of the display unit pitch of the liquid crystal display panel 804, and the polarization characteristic of the fine retardation plate 802 is set for each of a plurality of display units (that is, a plurality of display units). It is set so that the polarization of the transmitted light is different for each of the plurality of display units. Therefore, the polarization characteristics of the fine retardation plate 802 are different for each of the plurality of vertical lines (scanning lines) of the display unit of the liquid crystal display panel 804, and the direction of the light emitted is different for each of the plurality of vertical lines.
[0037]
Thus, since it is necessary to irradiate the display element (vertical line) of the liquid crystal display panel 804 with different light every time the polarization characteristic of the fine retardation plate 802 is repeated, the liquid crystal display panel transmits through the fine retardation plate 802. The light irradiated to 804 needs to suppress the diffusion in the left-right direction.
[0038]
That is, the region 802a that changes the phase of the light on the fine retardation plate 802 transmits the light transmitted through the polarizing filter 811a with the same polarization as the light transmitted through the polarizing filter 811b. Further, the region 802b of the fine retardation plate 802 where the phase of the light is not changed transmits the light transmitted through the polarizing filter 811b as it is. Then, the light emitted from the fine retardation plate 802 has the same polarization as the light transmitted through the polarizing filter 811b and enters the polarizing plate 803 provided on the light source side of the liquid crystal display panel 804.
[0039]
The polarizing plate 803 functions as a first polarizing plate and has a polarization characteristic that transmits light having the same polarization as the light transmitted through the fine retardation plate 802. That is, the light transmitted through the polarizing filter 811b is transmitted through the polarizing plate 803, and the light transmitted through the polarizing filter 811a is transmitted through the polarizing plate 803 with the polarization axis rotated by 90 degrees. In addition, the polarizing plate 805 functions as a second polarizing plate and has a polarization characteristic that transmits light having a polarization different from that of the polarizing plate 803 by 90 degrees.
[0040]
The fine retardation plate 802 and the polarizing plate 803 described above are configured to be bonded to each other, and the first region that transmits the light of the specific polarization as it is, and the polarization of the light of the polarization orthogonal to the light of the specific polarization The second region that transmits through rotation of the axis by 90 ° functions as a vertical stripe filter provided repeatedly in the horizontal direction.
[0041]
Such a fine retardation plate 802, a polarizing plate 803, and a polarizing plate 805 are attached to a liquid crystal display panel 804, and the fine retardation plate 802, a polarizing plate 803, a liquid crystal display panel 804, and a polarizing plate 805 are combined to form an image display device. Configure. At this time, when a voltage is applied to the liquid crystal, the liquid crystal molecules of the liquid crystal display panel 804 are aligned, so that the light transmitted through the fine retardation plate 802 is transmitted through the polarizing plate 805. On the other hand, in the state where no voltage is applied to the liquid crystal, the liquid crystal molecules of the liquid crystal display panel 804 are twisted and oriented by 90 degrees, so that the light transmitted through the fine retardation plate 802 is twisted by 90 degrees and the liquid crystal display panel 804 is twisted. Is not transmitted through the polarizing plate 805.
[0042]
Note that a diffuser functioning as a diffusing unit that diffuses light transmitted through the liquid crystal display panel in the vertical direction may be provided on the front surface side (observer side) of the polarizing plate 805. This diffuser is constituted by a lenticular lens, and semicircular unevenness (kamaboko-shaped unevenness) extending in the lateral direction is provided on the surface repeatedly in the vertical direction, and the other surface is flat. Yes. Then, it is attached to the front surface of the polarizing plate 805 so that the uneven surface is directed to the observer side and the plane is directed to the liquid crystal display panel 804 side. Therefore, the light that has passed through the liquid crystal display panel 804 and entered the diffuser is refracted by the projections and depressions so that the light path diffuses up and down and is emitted to the viewer side.
[0043]
FIG. 2 is a plan view showing an optical system of the image display apparatus according to the first embodiment of the present invention.
[0044]
As shown in FIG. 2, the light sources 801a (light emitting element 810a and polarizing filter 811a) and 801b (light emitting element 810b and polarizing filter 811b) are arranged in the housing 850 so that the distance between the two light sources is separated from the left and right sides. It is provided towards the corner of the body. Between the light sources in the housing 850, a substrate 852 on which a display control circuit for controlling the display of the image display device is configured is disposed in a space 851 at a position that does not overlap the optical path of the light emitted from the light source. . The space in which the substrate is arranged is partitioned from the space that becomes the optical path of the light in the housing by a wall 853 provided at a position that does not overlap the optical path of the light emitted from the light source.
[0045]
The light emitted from the light sources 801a and 801b spreads radially and reaches the liquid crystal display panel 804. In other words, light emitted from the light emitting element 810a of the first light source 801a and transmitted through the polarizing filter 811a (indicated by the one-dot chain line indicates the center of the optical path) reaches the Fresnel lens 812, and the traveling direction of the light can be changed by the Fresnel lens 812. Then, the light passes through the fine retardation plate 802, the polarizing plate 803, the liquid crystal display panel 804, and the polarizing plate 805 substantially vertically (slightly from the right side to the left side) and reaches the left eye.
[0046]
On the other hand, the light emitted from the light emitting element 810b of the second light source 801b and transmitted through the polarization filter 811b (shown by the broken line indicates the center of the optical path) reaches the Fresnel lens 812, and the traveling direction of the light is changed by the Fresnel lens 812. The light passes through the fine retardation plate 802, the polarizing plate 803, the liquid crystal display panel 804, and the polarizing plate 805 substantially vertically (slightly left to right) and reaches the right eye.
[0047]
In this way, light of different polarizations emitted from the light sources 801a and 801b is applied to the liquid crystal display panel 804 substantially perpendicularly by the Fresnel lens 812 as an optical means. That is, the light emitting element 810a, the polarizing filter 811a, the light emitting element 810b, and the polarizing filter 811b constitute a light source that irradiates the liquid crystal display panel 804 with light having different polarization planes through different paths, and the light transmitted through the liquid crystal display panel 804 is different. The light exits along the path and reaches the right or left eye. That is, the scanning line pitch of the liquid crystal display panel 804 and the repetition pitch of the polarization characteristics of the fine retardation plate 802 are made equal, and light coming from different directions is irradiated for each scanning line pitch of the liquid crystal display panel 804 and is different. Light is emitted in the direction.
[0048]
FIG. 3 is a diagram for explaining a path of light emitted from the image display device according to the first embodiment of the present invention. FIG. 3 (a) is transmitted through the polarization filter 811a of the first light source 801a. FIG. 3B shows the path of light reaching the left eye, and FIG. 3B shows the path of light reaching the right eye through the polarizing filter 811b of the second light source 801b.
[0049]
As shown in FIG. 3A, the light emitted from the light source 801a (the light emitting element 810a and the polarizing plate 811a) passes through the Fresnel lens 812, reaches the fine retardation plate 802, and rotates the polarization by 90 degrees. Then, the light is transmitted through the region 802a of the fine phase difference plate 802 (which transmits the light transmitted through the polarizing filter 811a), and further transmitted through the polarizing plate 803, the liquid crystal display panel 804, and the polarizing plate 805 to reach the left eye. . That is, the left eye image displayed by the display element at a position corresponding to the region 802a of the liquid crystal display panel 804 reaches the left eye.
[0050]
Since the regions 802b arranged alternately with the regions 802a of the fine retardation plate 802 do not change the polarization of light, the light from the polarization filter 811a does not pass through the polarizing plate 803, and the liquid crystal display panel 804 The right eye image displayed on the display element at the position corresponding to the region 802b does not reach the left eye.
[0051]
On the other hand, as shown in FIG. 3B, the light emitted from the light source 801b (light emitting element 810b, polarizing plate 811b) passes through the Fresnel lens 812 and reaches the fine retardation plate 802, and the polarizing filter 811b. Is transmitted through the region 802b of the fine retardation plate 802 that transmits the same polarized light, and then transmitted through the liquid crystal display panel 804 and the polarizing plate 805 to reach the right eye. That is, the right eye image displayed by the display element at a position corresponding to the region 802b of the liquid crystal display panel 804 reaches the right eye.
[0052]
Since the regions 802a alternately arranged with the regions 802b of the fine retardation plate 802 change the polarization of light, the light from the polarization filter 811b does not pass through the polarizing plate 803, and the liquid crystal display panel 804 The left eye image displayed on the display element at the position corresponding to the region 802a does not reach the right eye.
[0053]
FIG. 4 is a front view showing the fine retardation plate 802 of the image display apparatus according to the embodiment of the present invention.
[0054]
The fine retardation plate 802 is provided with a half-wave plate 821 on a light-transmitting substrate 822, and a region for changing the polarization of transmitted light is continuously repeated at a fine interval every predetermined interval. Has been placed. The polarization of light incident on this repeatedly arranged region is different between the polarization filter 811a and the polarization filter 811b. In the region where the polarization of the transmitted light is changed, the polarization axis of the incident light is rotated by 90 degrees and emitted. To do. The repetition of the polarization characteristics of the fine retardation plate 802 is substantially the same pitch as the display unit of the liquid crystal display panel 804.
[0055]
That is, the polarization axis of the light that has been transmitted through the polarization filter 811a and whose polarization axis has been rotated by 90 degrees with the fine phase plate is equal to the polarization axis of the light that has been transmitted through the polarization filter 811b and directly transmitted through the fine phase plate. Passes through the polarizing plate 805. The area of the fine retardation plate 2 that changes the polarization of the transmitted light and the area that does not change the polarization of the transmitted light are repeatedly and continuously arranged for each vertical line of the display unit of the liquid crystal display panel 4. The light transmitted through the fine retardation plate 2 and the polarizing plate 803 becomes the same polarized light that travels in different directions for each vertical line.
[0056]
As described above, the polarization characteristic of the fine retardation plate 802 is repeated as a pitch that is an integral multiple of the display unit pitch of the liquid crystal display panel 804, and the polarization characteristic of the fine retardation plate 802 is set for each of a plurality of display units. It is also possible to change the polarization of transmitted light for each of a plurality of display units.
[0057]
FIG. 5 is a block diagram showing a drive circuit of the image display apparatus according to the embodiment of the present invention.
[0058]
The main control circuit for driving the image display apparatus according to the embodiment of the present invention is provided with a CPU 111, a ROM 112 that stores programs and the like, and a RAM 113 that is a memory used as a work area when the CPU 111 operates. . These CPU 111, ROM 112 and RAM 113 are connected by a bus 118. The bus 118 includes an address bus and a data bus used by the CPU 111 for reading and writing data.
[0059]
A communication interface 115 that controls input / output with the outside, an input interface 116, and an output interface 117 are connected to the bus 118. The communication interface 115 is a data input / output unit for performing data communication according to a predetermined communication protocol. The input interface 116 and the output interface 117 input / output image data to be displayed on the image display device.
[0060]
In addition, a graphic display processor (GDP) 156 of a display control circuit is connected to the bus 118. The GDP 156 calculates the image data generated by the CPU 111, writes it in a frame buffer provided in the RAM 153, and generates signals (RGB, V BLANK, V_SYNC, H_SYNC) to be output to the image display device. A ROM 152 and a RAM 153 are connected to the GDP 156, and a work buffer for operating the GDP 156 and a frame buffer for storing display data are provided in the RAM 153. The ROM 152 stores programs and data necessary for the GDP 156 to operate.
[0061]
Further, an oscillator 158 that supplies a clock signal to the GDP 156 is connected to the GDP 156. The clock signal generated by the oscillator 158 defines the operation period of the GDP 156, and generates a period of a synchronization signal (for example, V_SYNC, V BLANK) output from the GDP 156.
[0062]
The RGB signal output from the GDP 156 is input to the γ correction circuit 159. The γ correction circuit 159 corrects the non-linear characteristic of the illuminance with respect to the signal voltage of the image display device, adjusts the display illuminance of the image display device, and generates an RGB signal to be output to the image display device.
[0063]
The synthesizing conversion device 170 is provided with a right-eye frame buffer, a left-eye frame buffer, and a stereoscopic frame buffer, writes the right-eye image sent from the GDP 156 to the right-eye frame buffer, and the left-eye image for the left-eye. Write to the frame buffer. Then, the right-eye image and the left-eye image are combined to generate a stereoscopic image, which is written in the stereoscopic frame buffer, and the stereoscopic image data is output to the image display device as an RGB signal.
[0064]
The generation of the stereoscopic image by combining the right-eye image and the left-eye image is combined with the right-eye image and the left-eye image at every interval of the half-wave plate 821 of the fine retardation plate 802. Specifically, since the half-wave plate 821 of the fine retardation plate 802 of the image display apparatus according to the present embodiment is arranged at intervals of the display unit of the liquid crystal display panel 804, the display unit of the liquid crystal display panel 804 is displayed. The stereoscopic image is displayed so that the right-eye image and the left-eye image are alternately displayed for each vertical line (scanning line).
[0065]
The left-eye image data transmitted from the GDP 156 during the output of the L signal is written into the left-eye frame buffer, and the right-eye image data transmitted from the GDP 156 during the output of the R signal is written into the right-eye frame buffer. Then, the left-eye image data written in the left-eye frame buffer and the right-eye image data written in the right-eye frame buffer are read for each scanning line and written into the stereoscopic frame buffer.
[0066]
In the image display device, a liquid crystal driver (LCD DRV) 181 and a backlight driver (BL DRV) 182 are provided. The liquid crystal driver (LCD DRV) 181 sequentially applies a voltage to the electrodes of the liquid crystal display panel based on the V BLANK signal, the V_SYNC signal, the H_SYNC signal, and the RGB signal sent from the synthesis conversion device 170 to the liquid crystal display panel. A composite image for stereoscopic viewing is displayed.
[0067]
The backlight driver 182 changes the brightness ratio of the liquid crystal display panel 804 by changing the duty ratio of the voltage applied to the light emitting element (backlight) 10 based on the DTY_CTR signal output from the GDP 156.
[0068]
FIG. 6 is a plan view showing an optical system of an image display apparatus according to a modification of the first embodiment of the present invention.
[0069]
As shown in FIG. 6, the light sources 801a (light emitting element 810a, polarizing filter 811a) and 801b (light emitting element 810b, polarizing filter 811b) are provided in the central part on the back side in the housing 850 so that both light sources approach each other. It has been. The light emitted from the light sources 801a and 801b spreads radially and reaches the liquid crystal display panel 804. In other words, light emitted from the light emitting element 810a of the first light source 801a and transmitted through the polarizing filter 811a (indicated by the one-dot chain line indicates the center of the optical path) reaches the Fresnel lens 812, and the traveling direction of the light can be changed by the Fresnel lens 812. Then, the light passes through the fine retardation plate 802, the polarizing plate 803, the liquid crystal display panel 804, and the polarizing plate 805 substantially vertically (slightly from the right side to the left side) and reaches the left eye.
[0070]
On the other hand, the light emitted from the light emitting element 810b of the second light source 801b and transmitted through the polarization filter 811b (shown by the broken line indicates the center of the optical path) reaches the Fresnel lens 812, and the traveling direction of the light is changed by the Fresnel lens 812. The light passes through the fine retardation plate 802, the polarizing plate 803, the liquid crystal display panel 804, and the polarizing plate 805 substantially vertically (slightly left to right) and reaches the right eye.
[0071]
In this way, light of different polarizations emitted from the light sources 801a and 801b is applied to the liquid crystal display panel 804 substantially perpendicularly by the Fresnel lens 812 as an optical means. That is, the light emitting element 810a, the polarizing filter 811a, the light emitting element 810b, and the polarizing filter 811b constitute a light source that irradiates the liquid crystal display panel 804 with light having different polarization planes through different paths, and the light transmitted through the liquid crystal display panel 804 is different. The light exits along the path and reaches the right or left eye. That is, the scanning line pitch of the liquid crystal display panel 804 and the repetition pitch of the polarization characteristics of the fine retardation plate 802 are made equal, and light coming from different directions is irradiated for each scanning line pitch of the liquid crystal display panel 804 and is different. Light is emitted in the direction.
[0072]
FIG. 7 is a perspective view of a light source of an image display apparatus according to a modification of the first embodiment of the present invention.
[0073]
The light emitting elements 810a and 810b are configured by light emitting elements (for example, U-shaped fluorescent tubes) formed in a U shape. That is, the right light emitting element 810a and the left light emitting element 810b are integrally formed by one fluorescent tube by the straight portions on both sides of the U-shaped fluorescent tube. At this time, the bent portion of the fluorescent tube between the right light emitting device 810a and the left light emitting device 810b is covered with the surface of the fluorescent tube with paint or tape so that light does not leak.
[0074]
In this way, when two linear light emitting elements (light sources) are formed by one light emitter, there is no difference in brightness between the left and right light sources due to the difference in characteristics of the light emitting elements. In particular, when a fluorescent tube is used as a light source, variation in brightness changes with time, and thus a light emitting element arranged in this manner is effective.
[0075]
FIG. 8 is a plan view showing an optical system of an image display apparatus according to a modification of the first embodiment of the present invention.
[0076]
In the modified example shown in FIG. 8, the light sources 801a and 801b are provided on the left and right sides in the housing 850, as in the example shown in FIG. 2, but the light sources 801a and 801b are red, green, and blue, respectively. Light emitting elements (three primary colors of light) are arranged side by side in the horizontal direction. The light of each color emitted from each light emitting element is applied to the Fresnel lens 812. The light emitting elements are arranged in the order of blue, green, and red from the inside. That is, the light emitting element is arranged so that light having a shorter wavelength is incident on the Fresnel lens 812 at a larger incident angle.
[0077]
Then, the light incident on the Fresnel lens 812 is refracted, passes through the liquid crystal display panel 804 and the like, and is emitted in the direction of the observer. The light emitting direction is adjusted so that the light emitting elements are emitted in the same direction using the property that the refractive index varies depending on the wavelength of the light. That is, since the blue light having a shorter wavelength has a smaller refraction angle, the light irradiated with the Fresnel lens 812 is emitted toward the observer without being greatly refracted.
[0078]
FIG. 9 is an explanatory diagram showing the configuration of the image display device according to the second embodiment of the present invention.
[0079]
The light source 801a includes a light emitting element 810a, a polarizing filter 811a, and a Fresnel lens 812a, and the light source 801b includes a light emitting element 810b, a polarizing filter 811b, and a Fresnel lens 812b. The light source 801a and the light source 801b are provided at symmetrical positions from a substantially central portion of the liquid crystal display panel 804. The light emitting elements 810a and 810b are configured by arranging linear light sources such as cold cathode tubes vertically or by arranging dot light sources such as white light emitting diodes vertically. The polarization characteristics of the polarization filter 811a and the polarization filter 811b are set so that the polarization of the transmitted light is different from each other (for example, the polarization of the light transmitted by the polarization filter 811a and the polarization filter 811b is shifted by 90 degrees). ing. The Fresnel lenses 812a and 812b have lens surfaces having concentric irregularities on one side surface and function as optical means. The polarizing filter 811a and the Fresnel lens 812a are arranged in an overlapping manner, and the polarizing filter 811b and the Fresnel lens 812b are arranged in an overlapping manner. The polarizing filter 811a and the Fresnel lens 812a are disposed on the front surface of the light source 810a, and the polarizing filter 811b and the Fresnel lens 812b are disposed on the front surface of the light source 810b.
[0080]
The light emitted from the light-emitting element 810a is transmitted only through the polarization filter 811a with a certain amount of polarized light, and the light emitted from the light-emitting element 810b is transmitted through the polarization filter 811b with a certain polarization different from that of the light-emitting element 810a. Only light is transmitted. Then, Fresnel lenses 812a and 812b functioning as convex lenses refract the light path of the light emitted from the light emitting elements 810a and 810b so as to be substantially parallel. In other words, the light emitting element 810a, the polarizing filter 811a, and the Fresnel lens 812a constitute a light source 801a that generates parallel light of a specific polarization. The light emitting element 810b, the polarization filter 811b, and the Fresnel lens 812b constitute a light source 801b that generates parallel light of a specific polarization. As will be described later, the light that has passed through the polarizing filter 811a reaches the left eye of the observer, and the light that has passed through the polarizing filter 811b reaches the right eye of the observer.
[0081]
At this time, since the light applied to the fine retardation plate 802 is substantially parallel light, it is also applied to the liquid crystal display panel 804 without spreading in the left-right direction. That is, light transmitted through a certain region of the fine retardation plate 802 is transmitted through a specific display unit portion of the liquid crystal display panel 804.
[0082]
Of the light irradiated to the liquid crystal display panel 804, the light that has passed through the polarizing filter 811 a and the light that has passed through the polarizing filter 811 b are incident on the fine retardation plate 802 at different angles and are transmitted through the liquid crystal display panel 804. Then, the light is emitted from the liquid crystal display panel 804 in different directions in the left and right directions.
[0083]
The liquid crystal display panel 804 has a liquid crystal that is twisted and aligned at a predetermined angle (for example, 90 degrees) between two transparent plates (for example, glass plates). It is composed. The light incident on the liquid crystal display panel is emitted with the polarization of the incident light shifted by 90 degrees in a state where no voltage is applied to the liquid crystal. On the other hand, in a state where a voltage is applied to the liquid crystal, the twist of the liquid crystal can be solved, so that incident light is emitted as it is with polarized light.
[0084]
A fine retardation film 802 and a polarizing plate 803 (first polarizing plate) are disposed on the light source 1 side of the liquid crystal display panel 804, and a polarizing plate 805 (second polarizing plate) is disposed on the viewer side. ing.
[0085]
In the fine phase difference plate 802, regions for changing the phase of transmitted light are repeatedly arranged at fine intervals. Specifically, a region 802a in which a half-wave plate 821 having a minute width is provided on a light-transmitting substrate 822 and a region 802b in which the half-wave plate 821 is not provided are fine. It is repeatedly provided at intervals. That is, the region 802a for changing the phase of light transmitted by the provided half-wave plate 821 and the phase of the transmitted light because the half-wave plate 821 is not provided are changed.
The non-existing region 802b is repeatedly provided at a fine interval. The half-wave plate 821 functions as a phase difference plate that changes the phase of transmitted light.
[0086]
The half-wave plate 821 is arranged so that its optical axis is inclined 45 degrees with respect to the polarization axis of the light transmitted through the polarization filter 811a, and the polarization axis of the light transmitted through the polarization filter 811a is rotated by 90 degrees and emitted. That is, the polarization axis of the light transmitted through the polarizing filter 811a is rotated by 90 degrees so as to be equal to the polarization of the light transmitted through the polarizing filter 811b. That is, the region 802b where the half-wave plate 821 is not provided transmits light having the same polarization as the polarizing plate 803 that has passed through the polarizing filter 811b, and the region 2a where the half-wave plate 821 is provided The light having passed through the polarizing filter 811a and whose polarizing axis is orthogonal to the polarizing plate 803 is rotated so as to be equal to the polarizing axis of the polarizing plate 803 and is emitted.
[0087]
The repetition of the polarization characteristics of the fine phase difference plate 802 is different in the polarization of light transmitted for each display unit (that is, for each vertical line of the display unit) at substantially the same pitch as the display unit of the liquid crystal display panel 804. Like that. Therefore, the polarization characteristics of the fine phase difference plate 802 corresponding to each vertical line (scanning line) of the display unit of the liquid crystal display panel 804 are different, and the direction of the emitted light is different for each vertical line.
[0088]
Alternatively, the polarization characteristic of the fine retardation plate 802 is repeated as an integer multiple of the display unit pitch of the liquid crystal display panel 804, and the polarization characteristic of the fine retardation plate 802 is set for each of a plurality of display units (that is, a plurality of display units). It is set so that the polarization of the transmitted light is different for each of the plurality of display units. Therefore, the polarization characteristics of the fine retardation plate 802 are different for each of the plurality of vertical lines (scanning lines) of the display unit of the liquid crystal display panel 804, and the direction of the light emitted is different for each of the plurality of vertical lines.
[0089]
Thus, since it is necessary to irradiate the display element (vertical line) of the liquid crystal display panel 804 with different light every time the polarization characteristics of the fine retardation plate are repeated, the liquid crystal display panel 804 transmits through the fine retardation plate 802. It is necessary that the light radiated on the surface is one that suppresses diffusion in the left-right direction.
[0090]
That is, the region 802a that changes the phase of the light on the fine retardation plate 802 transmits the light transmitted through the polarizing filter 811a with the same polarization as the light transmitted through the polarizing filter 811b. Further, the region 802b of the fine retardation plate 802 where the phase of the light is not changed transmits the light transmitted through the polarizing filter 811b as it is. Then, the light emitted from the fine retardation plate 802 has the same polarization as the light transmitted through the polarizing filter 811b and enters the polarizing plate 803 provided on the light source side of the liquid crystal display panel 804.
[0091]
The polarizing plate 803 functions as a first polarizing plate and has a polarization characteristic that transmits light having the same polarization as the light transmitted through the fine retardation plate 802. That is, the light transmitted through the polarizing filter 811b is transmitted through the polarizing plate 803, and the light transmitted through the polarizing filter 811a is transmitted through the polarizing plate 803 with the polarization axis rotated by 90 degrees. In addition, the polarizing plate 805 functions as a second polarizing plate and has a polarization characteristic that transmits light having a polarization different from that of the polarizing plate 803 by 90 degrees.
[0092]
Such a fine retardation plate 802, a polarizing plate 803, and a polarizing plate 805 are attached to a liquid crystal display panel 804, and the fine retardation plate 802, a polarizing plate 803, a liquid crystal display panel 804, and a polarizing plate 805 are combined to form an image display device. Configure. At this time, when a voltage is applied to the liquid crystal, the liquid crystal molecules of the liquid crystal display panel 804 are aligned, so that the light transmitted through the fine retardation plate 802 is transmitted through the polarizing plate 805. On the other hand, in the state where no voltage is applied to the liquid crystal, the liquid crystal molecules of the liquid crystal display panel 804 are twisted and oriented by 90 degrees, so that the light transmitted through the fine retardation plate 802 is twisted by 90 degrees and the liquid crystal display panel 804 is twisted. Is not transmitted through the polarizing plate 805.
[0093]
Note that a diffuser functioning as a diffusing unit that diffuses light transmitted through the liquid crystal display panel in the vertical direction may be provided on the front surface side (observer side) of the polarizing plate 805. This diffuser is constituted by a lenticular lens, and semicircular unevenness (kamaboko-shaped unevenness) extending in the lateral direction is provided on the surface repeatedly in the vertical direction, and the other surface is flat. Yes. Then, it is attached to the front surface of the polarizing plate 805 so that the uneven surface is directed to the observer side and the plane is directed to the liquid crystal display panel 804 side. Therefore, the light that has passed through the liquid crystal display panel 804 and entered the diffuser is refracted by the projections and depressions so that the light path diffuses up and down and is emitted to the viewer side.
[0094]
FIG. 10 is a plan view showing an optical system of the image display apparatus according to the second embodiment of the present invention.
[0095]
Light radiated from the light emitting element 810a of the first light source 801a (indicating the center of the optical path by a one-dot chain line) spreads radially and reaches the polarizing filter 811a and the Fresnel lens 812a, and is refracted into parallel light by the Fresnel lens 812a. , Reaches the fine retardation plate 802, rotates the polarized light by 90 degrees and emits the light (transmits the light transmitted through the polarizing filter 811 a), passes through the region 802 a of the fine retardation plate 802, and further polarizing plate 803, liquid crystal The light passes through the display panel 804 and the polarizing plate 805 substantially vertically (slightly from the right side to the left side) and reaches the left eye. That is, the left eye image displayed by the display element at a position corresponding to the region 802a of the liquid crystal display panel 804 reaches the left eye.
[0096]
The regions 802b arranged alternately with the regions 802a of the fine retardation plate 802 do not transmit the light transmitted through the region 802a, but have different polarization light (polarized light orthogonal to each other). The right eye image displayed on the display element at the position corresponding to the region 802b of the liquid crystal display panel 804 does not reach the left eye.
[0097]
On the other hand, light emitted from the light emitting element 810b of the second light source 801b (the center of the optical path is indicated by a broken line) spreads radially and reaches the polarizing filter 811b and the Fresnel lens 812b, and is refracted into parallel light by the Fresnel lens 812b. The liquid crystal display panel 804 and the polarizing plate 805 are made substantially vertical (slightly on the left side) through the region 802b of the fine retardation plate 802 that reaches the fine retardation plate 802 and transmits the same polarized light as the polarizing filter 811b. To the right eye). That is, the right eye image displayed by the display element at a position corresponding to the region 802b of the liquid crystal display panel 804 reaches the right eye.
[0098]
Since the regions 802a alternately arranged with the regions 802b of the fine retardation plate 802 change the polarization of light, the light from the polarization filter 811b does not pass through the polarizing plate 803, and the liquid crystal display panel 804 The left eye image displayed on the display element at the position corresponding to the region 802a does not reach the right eye.
[0099]
In this manner, light of different polarizations radiated from the light emitting elements 810a and 810b is irradiated to the liquid crystal display panel 804 substantially perpendicularly by the Fresnel lenses 812a and 812b as optical means. In other words, different paths of parallel light having different polarization planes are used depending on the first light source 801a (light emitting element 810a, polarizing filter 811a, Fresnel lens 812a) and the second light source 801b (light emitting element 810b, polarizing filter 811b, Fresnel lens 812b). A light source for irradiating the liquid crystal display panel 804 is configured, and light transmitted through the liquid crystal display panel 804 is emitted through different paths to reach the right eye or the left eye. That is, the scanning line pitch of the liquid crystal display panel 804 and the repetition pitch of the polarization characteristics of the fine retardation plate 802 are made equal, and light coming from different directions is irradiated for each scanning line pitch of the liquid crystal display panel 804 and is different. Light is emitted in the direction.
[0100]
FIG. 11 is a front view showing a configuration of the entire gaming machine (CR machine with a card ball lending unit) according to the embodiment of the present invention.
[0101]
The front frame 3 of the gaming machine (pachinko gaming machine) 1 is assembled to the main body frame (outer frame) 4 so as to be able to open and close via a hinge 5, and the game board 6 is attached to a storage frame attached to the back surface of the front frame 3. Stored.
[0102]
A game area surrounded by guide rails is formed on the surface of the game board 6, and a center case 11 provided with an image display device (special symbol display device) 8 is disposed at substantially the center of the game area. In the lower part, a variable winning device 10 having a large winning port is arranged, and in the gaming area, each winning port 12 to 15, a starting port 16, a normal symbol display 7, a normal variable winning device 9 and the like are arranged. Yes. A cover glass 18 as a front constituent member that covers the front surface of the game board 6 is attached to the front frame 3.
[0103]
The display screen of the image display device 8 is composed of an LCD (liquid crystal display), and the image display device of the first embodiment or the second embodiment described above is used. A plurality of variable display areas are provided in an area (display area) where an image of the display screen can be displayed, and identification information (special symbol, normal symbol) and a character that produces a variable display game are displayed in each variable display region. Is displayed. In other words, in the variable display areas provided on the left, middle, and right of the display screen, symbols assigned as identification information (for example, numbers from “0” to “9” and English letters “A” and “B”) are assigned. Twelve types of characters) are displayed in a variable manner, and a variable display game is played. In addition, an image based on the progress of the game is displayed on the display screen.
[0104]
Below the image display device 8, a start port 16 having a normal variation winning device (ordinary electric accessory) 9 is disposed, and a normal symbol start gate 14 is disposed at a predetermined position on the left and right of the game area.
[0105]
The image display device 8, the start port 16, and the variable winning device 10 provided on the game board are arranged at the center in the vertical direction of the game board with their centers aligned with the center line of the game board. That is, the image display device 8, the start port 16, and the variable winning device 10 are arranged so that their centers coincide with each other, and the centers of the respective components coincide with the centers of the game boards. Then, with respect to a plane (plane A whose position is indicated by a dotted line in FIG. 2) perpendicular to the display surface of the image display device 8 (game board surface provided with a game area) and including the center line of the image display device 8 The light source 801a and the light source 801b of the image display device 8 are provided at symmetrical positions, and the light emitted from the light source 801a and the light emitted from the light source 801b are orthogonal to the display surface of the image display device 8 and display an image. Radiated in the direction of interest relative to the plane containing the center line of the device 8. Therefore, if the player plays a game at a position facing the gaming machine, the image can be stereoscopically viewed in a balanced manner when viewed from either the left or right direction.
[0106]
In the gaming machine of the present embodiment, a game is played by launching a game ball (pachinko ball) from a hit ball launching device (not shown) toward the game area, and the launched game balls are placed in various places in the game area. The game area is made to flow down while changing the rolling direction by the rolling guide member 12 such as a windmill arranged at the top, and the start opening 16, the general winning opening 15, the special variable winning apparatus 10 is won, or at the bottom of the gaming area It is discharged from the provided outlet. The winning of game balls to the general winning opening 15 includes N winning sensors 51.1 to 51. N (see FIG. 12).
[0107]
When a game ball wins the start opening 16, the general winning opening 15, and the special variable winning apparatus (large winning opening) 10, the number of winning balls corresponding to the type of winning opening is discharged from the payout unit (discharge device), It is supplied to the supply tray 21.
[0108]
When a game ball is won at the starting port 16, the image display device 8 starts a variable display game in which the identification information composed of the numbers and the like described above is sequentially displayed, and displays an image relating to the variable display game. When winning at the start port 16 is made at a predetermined timing (specifically, when the special symbol random number counter value at the time of winning detection is a winning value), a big win state is obtained, and three display symbols are aligned. Stop at (big hit symbol). At this time, the special variable prize-winning device 10 is in a closed state in which the big prize opening does not accept a game ball for a predetermined time (for example, 30 seconds) by energizing the big prize solenoid 10A (see FIG. 12). From an unfavorable state) to an open state (a state advantageous to the player) in which a game ball can be easily received. In other words, since the special winning opening is greatly opened for a predetermined time, a game value is given that the player can acquire many game balls during this time.
[0109]
The winning of the game ball to the start port 16 is detected by a special symbol start sensor 52 (see FIG. 12). The special symbol random number counter value extracted according to the passing timing of the game ball is stored in a predetermined storage area (special symbol winning storage area) in the game control device 100 for a predetermined number of times as a special symbol winning memory (for example, at maximum). Memorize up to 4 times). The stored number of special symbol winning memories is displayed in a special symbol storage state display area provided in a part of the display screen of the image display device 8. The game control device 100 plays a variable display game on the image display device 8 based on the special symbol winning memory.
[0110]
The winning of the game ball to the special variation winning device 10 is detected by the count sensor 54 and the continuation sensor 55 (see FIG. 12).
[0111]
When the game ball passes to the normal symbol start gate 14, the normal symbol display unit 7 starts to display the variation of the normal symbol (for example, a symbol consisting of a single digit number). When the passage to the normal symbol start gate 14 is detected at a predetermined timing (specifically, when the normal symbol random number counter value at the time of passage detection is a winning value), the normal symbol is hit, The symbol stops at the winning symbol (hit number). At this time, the normal variation winning device 9 provided in front of the start port 16 is energized to the normal electric accessory solenoid 9A (see FIG. 12), and the entrance to the start port 16 is kept for a predetermined time (for example, 0.5). Second), the possibility of winning the game ball at the start port 16 is increased.
[0112]
The passing of the game ball to the normal symbol start gate 14 is detected by a normal symbol start sensor 53 (see FIG. 12). The normal symbol random number counter value extracted based on the passing timing of the game ball is stored in a predetermined storage area (ordinary symbol winning storage area) in the gaming control device 100 for a predetermined number of times as a normal symbol winning storage (for example, at most). Memorize up to 4 times). The stored number of the normal symbol winning memory is displayed on the normal symbol memory state display 19 including a predetermined number of LEDs provided on the right side of the variable winning device 10. The game control device 100 performs a lottery on the normal symbols based on the normal symbol winning memory.
[0113]
A decoration light-emitting device such as a decoration lamp or LED is provided at a key point of the gaming machine. That is, a decoration lamp that emits light according to the progress of the game is provided in the center case 11 provided in the center of the game board and the attacker provided in the lower part of the game board (around the variable winning device 10). Further, side case lamps are provided on the upper left and right sides of the game board, and side lamps 33 are provided on the left and right sides of the game board. The game frame is provided with a game frame decoration lamp. These lamps are turned on as the game progresses so that the player's interest in the game continues. In addition, the front frame 3 above the cover glass 18 is provided with a first notification lamp 31 and a second notification lamp 32 which notify a state such as abnormal discharge of the sphere by lighting.
[0114]
An upper plate 21 for supplying a ball to the ball hitting device is disposed on the open / close panel 20 below the front frame 3, and a lower plate 23, an operation unit 24 of the ball hitting device, and the like are arranged on the fixed panel 22. In addition, a sound output device (speaker) is provided.
[0115]
An operation panel 26 for the card ball lending unit 2 is formed on the outer surface of the upper plate 21 of the gaming machine 1, and a card balance display unit (not shown) for displaying the balance of the card, a ball lending switch 28 for instructing ball lending, a card A card return switch 30 or the like for instructing the return of the card is provided.
[0116]
The card lending unit 2 includes a card reader / writer and a ball lending control device for reading and writing data of a card (a prepaid card or the like) inserted into the card insertion unit 25 on the front surface.
[0117]
FIG. 12 is a block diagram showing a part of a control system centering on the game control device 100 of the gaming machine according to the embodiment of the present invention.
[0118]
The game control device 100 is a main control device that controls the game in an integrated manner, a CPU that controls game control, a ROM that stores invariant information for game control, and a RAM that is used as a work area during game control Is composed of a game microcomputer 111, an input interface 112, an output interface 113, an oscillator 104, and the like.
[0119]
The gaming microcomputer 111 has various detection devices (general prize opening sensors 51.1 to 51.N, special symbol start sensor 52, normal symbol start sensor 53, count sensor 54, continuation sensor 55) via the input interface 112. In response to the detection signal from, various processes such as a big win lottery are performed. Then, via the output interface 113, various control devices (production control device 150, discharge control device 200, decoration control device 250, sound control device 300), normal symbol display 7, normal electric accessory solenoid 9A, large prize opening A command signal is transmitted to the solenoid 10A or the like to control the game in an integrated manner.
[0120]
The discharge control device 200 controls the operation of the payout unit based on the prize ball command signal from the game control device 100 and discharges the prize ball. Further, based on the ball rental request from the card ball rental unit 2, the operation of the payout unit is controlled to discharge the ball rental.
[0121]
Based on the command signal from the game control device 100, the decoration control device 250 is a decoration light emitting device such as a decoration lamp or LED (decoration lamp in the center case 11, decoration lamp in the attacker, side lamp 33, side case lamp. The game frame decoration lamp, the notification lamp 31 and the like), and the display of the normal symbol winning memory display 19 is controlled to function as a lamp control device.
[0122]
The sound control device 300 functions as a sound control device by controlling sound effects output from the speaker.
[0123]
Communication from the game control device 100 to various subordinate control devices (the effect control device 150, the discharge control device 200, the decoration control device 250, and the sound control device 300) is unidirectional from the game control device 100 to the subordinate control device. Only communication is allowed. Thereby, it is possible to prevent an illegal signal from being input to the game control device 100 from the dependent control device side.
[0124]
A power supply device (not shown) of the gaming machine includes a backup power supply unit and a power failure monitoring circuit in addition to the power supply circuit. When the power failure monitoring circuit detects a predetermined voltage drop of the power supply device, the power failure monitoring circuit sequentially outputs a power failure detection signal and a reset signal to the game control device 100 and the like. When the game control device 100 receives a power failure detection signal, the game control device 100 performs a predetermined power failure process, and when it receives a reset signal, stops the operation of the CPU. The backup power supply unit supplies backup power to the RAM of the game control device 100 or the like to back up game data (including game information, game control information: variable display game information) and the like.
[0125]
The effect control device 150 performs image display control, and functions as an effect control means together with the game control device 100 and the composite conversion device 170. The effect control device 150 stores a CPU 151, a VDC (Video Display Controller) 156, a RAM 153, an interface 155, a ROM 152 storing programs, and image data (design data, background image data, moving image character data, texture data, etc.). The font ROM 157 includes an oscillator 158 that generates a clock signal for generating a synchronization signal and a strobe signal.
[0126]
The CPU 151 executes a program stored in the ROM 152, and based on a signal from the game control device 100, image control information for a predetermined variable display game (symbol display information including sprite data, polygon data, etc., background screen) Information, moving image object screen information, etc.) to instruct the VDC 156 to alternately generate the image signal for the right eye and the image signal for the left eye. An L / R signal is generated in accordance with the generation timing of the right-eye image signal and the left-eye image signal, and it is identified whether the generated image signal is a right-eye image signal or a left-eye image signal. It is possible.
[0127]
The VDC 156 performs, for example, polygon drawing (or normal bitmap drawing) of an image based on the image data stored in the font ROM 157 and the content calculated by the CPU 151, and a predetermined texture for each polygon. Is pasted and stored in the RAM 153 as a frame buffer. Then, the VDC 156 transmits the image in the RAM 153 to the LCD side (the composite conversion device 170) at a predetermined timing (vertical synchronization signal V_SYNC, horizontal synchronization signal H_SYNC).
[0128]
The drawing processing performed by the VDC 156 performs point drawing, line drawing, triangle drawing, polygon drawing, and texture mapping, alpha blending, shading processing (glow shading, etc.), hidden surface removal (Z buffer processing, etc.), and γ correction. The image signal is output to the composition conversion device 170 via the circuit 159.
[0129]
Note that the VDC 156 may temporarily store the drawn image data in the RAM 153 as a frame buffer, and then output the image data to the synthesizing / conversion device 170 in accordance with a synchronization signal (V_SYNC or the like).
[0130]
Here, as the frame buffer, a plurality of frame buffers are respectively set in a predetermined storage area of the RAM 153, and the VDC 156 can also superimpose (overlay) an arbitrary image and output it.
[0131]
An oscillator 158 that supplies a clock signal is connected to the VDC 156. The clock signal generated by the oscillator 158 defines the operation period of the VDC 156, generates a signal output from the VDC 156, for example, a vertical synchronization signal (V_SYNC) and a horizontal synchronization signal (H_SYNC), and generates a composite conversion device 170 and an image. It is output to the display device 8.
[0132]
The RGB signal output from the VDC 156 is input to the γ correction circuit 159. The γ correction circuit 159 corrects the non-linear characteristic of the illuminance with respect to the signal voltage of the image display device 8, adjusts the display illuminance of the image display device 8, and generates an RGB signal to be output to the image display device 8. .
[0133]
Further, the CPU 151 of the effect control device 150 identifies whether the image data (RGB) to be output to the composite conversion device 170 is a left-eye image or a right-eye image based on the clock signal of the oscillator 158. The L / R signal is output.
[0134]
Further, the CPU 151 controls the luminance (the amount of light emitted from the backlight) of the image display device 8 based on the state of variable display (for example, whether it is a normal variable display game or a jackpot display) and the state of the game. Therefore, the duty control signal DTY_CTR is generated based on the clock signal of the oscillator 158 and output to the image display device 8.
[0135]
Based on the L / R signal output from the CPU 151, the composite conversion device 170 determines whether the image signal sent from the VDC 156 is a right-eye image signal or a left-eye image signal. The synthesizing / conversion device 170 includes a right-eye frame buffer, a left-eye frame buffer, and a stereoscopic frame buffer. The determined right-eye image signal is written to the right-eye frame buffer, and the left-eye image signal is written. Write to the left eye frame buffer. Then, the right-eye image and the left-eye image are combined to generate a stereoscopic image, the stereoscopic image signal is written in the stereoscopic frame buffer, and the stereoscopic image data is converted into an RGB signal as an image display device. 8 is output.
[0136]
As described above, the right-eye image and the left-eye image are obtained for each vertical line (scanning line) of the display unit of the liquid crystal display by the stereoscopic image signal obtained by combining the right-eye image and the left-eye image. A stereoscopic image is displayed so as to be displayed alternately.
[0137]
Specifically, the right eye image and the left eye image are generated with parallax based on the depth information of the stereoscopic image information (display object). In the case of polygon drawing, rendering is performed with a left-eye viewpoint and a right-eye viewpoint to generate a right-eye image and a left-eye image, respectively. When using sprite data, drawing is performed by shifting in the left-right direction by the amount of parallax.
[0138]
In this way, the left-eye image and the right-eye image are alternately generated, and the left-eye image is stored in the left-eye frame buffer, and the right-eye image is stored in the right-eye frame buffer. That is, the left-eye image data transmitted from the VDC 156 during the output of the L signal is written into the left-eye frame buffer, and the right-eye image data transmitted from the VDC 156 during the output of the R signal is written into the right-eye frame buffer. Then, the left-eye image data written in the left-eye frame buffer and the right-eye image data written in the right-eye frame buffer for each scanning line are read and written into the stereoscopic frame buffer.
[0139]
When the CPU 151, the VDP 156, and the composite conversion device 170 function as described above, a left-eye image and a right-eye image are generated, binocular parallax is generated depending on the display position, and the image is converted into a three-dimensional stereoscopic image. Display position control means is configured by performing display control so as to be recognized.
[0140]
In the image display device 8, a liquid crystal driver (LCD DRV) 181 and a backlight driver (BL DRV) 182 are provided. The liquid crystal driver 181 sequentially applies voltages to the electrodes of the liquid crystal display panel 804 on the basis of the V_SYNC signal, the H_SYNC signal, and the RGB signal sent from the composite conversion device 170, and the stereoscopic image is displayed on the image display device 8. Is displayed.
[0141]
The backlight driver 182 changes the brightness ratio of the image display device 8 by changing the duty ratio of the voltage applied to the backlight based on the DTY_CTR signal output from the VDC 156.
[0142]
In other words, the game control device 100 extracts and stores a predetermined random number (special symbol random number, jackpot random number) when a game ball launched into the game area wins the start opening 16. Then, the game control device 100 edits the display control command signal that instructs the effect control device 150 to change display, and transmits the edited display control command signal. When receiving the display control command signal, the CPU 151 of the effect control device 150 reads display image data corresponding to the display control command signal from the font ROM 157 (storage means), and cooperates with the VDC 156 and the composite conversion device 170. Display data to be displayed on the image display device 8 is generated. Thus, the lottery means and the game control means are configured by the function of the game control device 100. Further, the effect control device 150 and the composite conversion device 170 function to constitute a calculation means.
[0143]
A buffer circuit 160 serving as a signal transmission direction restricting means is provided in front of the interface 155 that receives the effect control command signal from the game control device 100, and only signal input from the game control device 100 to the effect control device 150 is allowed. Thus, signal output from the effect control device 150 to the game control device 100 is prohibited. Note that when performing bidirectional communication between the game control device 100 and the effect control device 150, a bidirectional buffer may be used for the buffer circuit 160.
[0144]
The LED 34 is turned on while the three-dimensional stereoscopic image is displayed, and is controlled by the CPU 151 to be turned on / off by applying a voltage to the LED 34 via the driver 161. That is, when a stereoscopically visible image is displayed on the image display device 8, the display mode is changed (for example, it is turned on or the emission color is changed) to display stereoscopically. To the player.
[0145]
In addition, it can also comprise so that a player's stereoscopic vision may be assisted by carrying out the auxiliary display which gives a feeling of depth to the near side of the image display apparatus 8 by lighting of LED34.
[0146]
In the embodiment described above, the decoration control device 250, the sound control device 300, and the effect control device 150 are provided separately. Of the subordinate control devices, the decoration control device 250 and the sound control device 300 are used as the effect control device 150. In addition, the decoration control device 250 and the sound control device 300 may be configured integrally with the effect control device 150.
[0147]
The embodiments disclosed herein are illustrative and non-restrictive in every respect. The scope of the present invention is defined not by the above description of the invention but by the scope of the claims, and is intended to include all modifications within the scope and meaning equivalent to the scope of the claims.
[Brief description of the drawings]
FIG. 1 is a configuration diagram of an image display apparatus according to a first embodiment of the present invention.
FIG. 2 is a plan view of an optical system of the image display apparatus according to the first embodiment of the present invention.
FIG. 3 is an explanatory diagram of a path of light emitted from the image display device according to the first embodiment of this invention.
FIG. 4 is a front view of a fine retardation plate of the image display device according to the first embodiment of the present invention.
FIG. 5 is a block diagram of a drive circuit of the image display device according to the first embodiment of the present invention.
FIG. 6 is a plan view of an optical system of an image display apparatus according to a modification of the first embodiment of the present invention.
FIG. 7 is a perspective view of a light source of an image display apparatus according to a modification of the first embodiment of the present invention.
FIG. 8 is a plan view of an optical system of an image display apparatus according to a modification of the first embodiment of the present invention.
FIG. 9 is a diagram showing a part of the configuration of an image display apparatus according to a second embodiment of the present invention.
FIG. 10 is a cross-sectional view of a diffuser of an image display device according to a second embodiment of the present invention.
FIG. 11 is a front view showing the configuration of the entire gaming machine according to the embodiment of the present invention.
FIG. 12 is a block diagram of a control system of the gaming machine according to the embodiment of the present invention.
[Explanation of symbols]
1 gaming machine
8 Image display device
100 game control device
150 Production control device
801 Light source
810 Light emitting device
811 Polarizing filter
812 Fresnel lens
813 Reflector
802 Fine retardation plate
803 Polarizing plate (first polarizing plate)
804 LCD panel
805 Polarizing plate (second polarizing plate)

Claims (4)

A liquid crystal display panel capable of transmitting the light irradiated from the rear;
A light source that irradiates the liquid crystal display panel with a first light having a specific polarization and a second light having a polarization axis orthogonal to the first light;
Optical means for refracting the light emitted from the light source in a direction reaching each of the left and right eyes;
A stripe disposed between the liquid crystal display panel and the light source, wherein a first region that transmits the first light and a second region that transmits the second light are repeatedly provided in a certain direction. A filter,
A polarizing plate having a polarization characteristic that blocks light transmitted through the liquid crystal display panel, either when the liquid crystal display panel is energized or not energized,
The striped filter is formed by repeatedly providing the first region and the second region in the horizontal direction,
The light source includes a first light source that generates the first polarized light and a second light source that generates the second polarized light, which are individually symmetrically positioned from a substantially central portion of the liquid crystal display panel. Placed and configured,
The optical means includes
Between the first light source and the liquid crystal display panel, and between the second light source and the liquid crystal display panel, each provided individually corresponding to each light source,
Wherein the first light source and the light generated from the second light source, one of said optical means may be refracted to reach the left eye and transmitting light from one of the light source, the other of said optical means, other the image display apparatus characterized by refracting to reach the right eye passes through the light from the light source.   The image display device according to claim 1, wherein the first light source and the second light source have a vertically long shape.   3. The image display device according to claim 1, wherein each of the first light source and the second light source includes a light emitting element that generates light of three primary colors. Fluctuation for variably displaying identification information displayed on the image display device, comprising: an image display device provided with a display area for variably displaying a plurality of identification information; and variability display control means for controlling variation display of the identification information. In a gaming machine capable of starting a special game state in which a display game is performed and a specific game value is given in relation to a result mode of the variable display game,
The image display device includes:
A liquid crystal display panel capable of transmitting the light irradiated from the rear;
A light source that irradiates the liquid crystal display panel with a first light having a specific polarization and a second light having a polarization axis orthogonal to the first light;
Optical means for refracting the light emitted from the light source in a direction reaching each of the left and right eyes;
A stripe disposed between the liquid crystal display panel and the light source, wherein a first region that transmits the first light and a second region that transmits the second light are repeatedly provided in a certain direction. A filter,
In any of the energization time or non-energization of the liquid crystal display panel, Bei example and a polarizing plate having a polarization characteristic of blocking light transmitted through the liquid crystal display panel,
The striped filter is formed by repeatedly providing the first region and the second region in the horizontal direction,
The light source includes a first light source that generates the first polarized light and a second light source that generates the second polarized light, which are individually symmetrically positioned from a substantially central portion of the liquid crystal display panel. Placed and configured,
The optical means includes
Between the first light source and the liquid crystal display panel, and between the second light source and the liquid crystal display panel, each provided individually corresponding to each light source,
Wherein the first light source and the light generated from the second light source, one of said optical means may be refracted to reach the left eye and transmitting light from one of the light source, the other of said optical means, other gaming machine for causing refracted to reach the right eye passes through the light from the light source.

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