JP2002287089A - Three-dimensional video display device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a three-dimensional video display device which enables an observer to recognize three-dimensional video more realistically. SOLUTION: A light source device 2 comprises a back light 21 and a pinhole array plate 22. A liquid crystal display panel driving part 5 supplies a pixel drive signal to a liquid crystal display panel 3 to form a pixel area 3a formed of pixels corresponding to the respective pinholes 22a. Each pixel of the pixel area 3a controls the quantity of transmitted light of a light beam in each direction from the corresponding pinhole 22a, and consequently the intensity of the light beam in each direction is reproduced. The lines connecting the centers of the respective pinholes 22a and the centers of the pixel areas 3a are not parallel to one another and cross at one point at a position corresponding to the standard distance between the video display 8 panel 3 and observer Z; and light beams are efficiently converged on the standard observation position, so that the observer Z can recognize three-dimensional video more realistically.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a three-dimensional image display device using a so-called light beam reproducing system.

[0002]

2. Description of the Related Art Conventionally, a parallax barrier method, a lenticular lens method, and the like have been known as methods for achieving stereoscopic image display without requiring special glasses.
In these methods, a right-eye image and a left-eye image having binocular parallax are alternately displayed on a display screen in a strip shape, and a stereoscopic effect in the left-right direction is obtained, but a stereoscopic effect in the vertical direction is obtained. There are complaints that cannot be obtained. Further, if the position deviates from the appropriate viewing position, a phenomenon such as reverse vision in which the left eye image is incident on the right eye and the right eye image is incident on the left eye occurs, and there is also an inconvenience that the viewing position cannot be freely selected.

On the other hand, in recent years, a three-dimensional image display method called a light beam reproduction method capable of freely selecting a viewing position has been proposed. This light beam reproduction method is a method of recording and reproducing information on light rays passing through a plane (that is, the direction of light rays and the spread of light rays corresponding to scattered light from an object) on a plane. For example, as shown in FIG. 7A, it can be configured by a backlight 51, a pinhole array plate 52, and a liquid crystal display panel 53. Here, it can be considered that light rays are emitted from the pinholes 52a of the pinhole array plate 52 in several directions within a predetermined range. Each liquid crystal display panel 53 has a pinhole 52a.
Corresponding to the pixel area (for example, 9 to 20 horizontal, 3 to 20 vertical)
53a) are formed. Lines connecting the center of each pinhole 52a and the center of the pixel area 53a are parallel to each other. Each pixel in the pixel area 53a controls the amount of light transmitted from the corresponding pinhole 52a in each direction, thereby reproducing the intensity of the light in each direction. More specifically, for example, as shown in FIG.
the pixels a ₁ pixel region 53a ₁ which will receive a light beam from a _1, amount of light transmission which represents a portion A ₁ of object A is set, will receive a light beam from the pinhole 52a ₂ pixels the pixel a ₂ regions 53a _2, amount of light transmission which represents a portion a ₂ of the object a is set, the pinhole 52a
The pixel a ₃ pixel region 53a ₃ which will receive a light beam from the _3, so that the light transmission amount of the portion A ₃ representing the object A is set, corresponding to a predetermined point of the object A Thus, the observer Z three-dimensionally recognizes the object A by reproducing the light transmission amount in each pixel.

[0004]

By the way, in such a three-dimensional image display apparatus of the light beam reproducing system, although the observer Z can be made to recognize the image three-dimensionally according to the above-described principle, a more realistic feeling is obtained. An issue is to make the observer Z recognize a certain three-dimensional feeling.

In view of the above circumstances, an object of the present invention is to provide a three-dimensional image display device that allows a viewer to recognize a more realistic three-dimensional image.

[0006]

In order to solve the above-mentioned problems, a three-dimensional image display device according to the present invention includes a plurality of dot-like light emitting portions for providing a group of light beams corresponding to scattered light from an object at predetermined intervals. A light source device arranged in a plane, an image display panel arranged on the light emitting side of the light source device, and a display image to be displayed in each pixel region of the image display panel corresponding to each light emitting portion are set. And a display panel driving unit, wherein a line connecting the center of each light emitting unit and the center of each pixel region corresponding to each light emitting unit is set to be non-parallel to each other. It is characterized by.

[0007] Further, the three-dimensional image display device of the present invention comprises:
An image display panel for displaying an image, and light transmitting portions on which image light from the image display panel is incident are arranged in a plane at predetermined intervals, and point light transmission that provides a group of rays corresponding to scattered light from an object. Part forming panel, and a display panel driving means for setting a display image to be displayed in each pixel region of the image display panel corresponding to each light transmitting part, a three-dimensional image display device comprising: A line connecting the center and the center of each pixel region corresponding to each light transmitting portion is set to be non-parallel to each other.

With these configurations, the lines connecting the center of each light emitting portion or each light transmitting portion and the center of each pixel region corresponding to each light emitting portion or each light transmitting portion are parallel to each other. In comparison with, an effective effect is produced in causing the observer to recognize the three-dimensional image.

In particular, a line connecting the center of each light emitting portion or each light transmitting portion and the center of each pixel region corresponding to each light emitting portion or each light transmitting portion corresponds to a standard between the image display panel and the observer. At a position that corresponds to a typical distance, light rays efficiently converge at a standard observation position, and the transition of the image when the observer moves his / her head becomes smoother, providing a more realistic feeling. This makes it possible for the observer to recognize a certain three-dimensional feeling. Also, if the line connecting the center of each light emitting portion or each light transmitting portion and the center of each pixel region corresponding to each light emitting portion or each light transmitting portion is concentrated on the region where the object is to be reproduced Therefore, the number of light rays representing the object existing in the area increases, the area where the object can be seen increases, and the observer can recognize a more realistic three-dimensional feeling.

[0010] Further, the three-dimensional image display device of the present invention comprises:
A light source device in which point light emitting portions that provide a group of rays corresponding to scattered light from an object are arranged in a plane at predetermined intervals, and an image display panel arranged on the light emitting side of the light source device,
Display panel driving means for setting a display image to be displayed in each pixel region of the image display panel corresponding to each light emitting unit,
In the three-dimensional image display device comprising: a line connecting the center of each light emitting portion and the center of each pixel region corresponding to each light emitting portion is set to be arbitrarily non-parallel to each other. It is characterized by having.

[0011] Further, the three-dimensional image display device of the present invention comprises:
An image display panel for displaying an image, and light transmitting portions on which image light from the image display panel is incident are arranged in a plane at predetermined intervals, and point light transmission that provides a group of rays corresponding to scattered light from an object. Part forming panel, and a display panel driving means for setting a display image to be displayed in each pixel region of the image display panel corresponding to each light transmitting part, a three-dimensional image display device comprising: A line connecting the center and the center of each pixel region corresponding to each light transmitting portion is set so as to be arbitrarily nonparallel to each other.

With these configurations, a line connecting the center of each light emitting portion or each light transmitting portion and the center of each pixel region corresponding to each light emitting portion or each light transmitting portion is fixedly set. In this case, a more effective action is produced in causing the observer to recognize the three-dimensional image as compared with a case where the three-dimensional image is recognized.

In particular, a line connecting the center of each light emitting portion or each light transmitting portion and the center of each pixel region corresponding to each light emitting portion or each light transmitting portion corresponds to a region where an object is to be reproduced. By focusing on the area, the number of light rays representing the object can be increased following the position change of the area, and even in an image where the position of the object changes, the area where the object can be seen at each position can be increased. It is possible to make the observer recognize the increased and more realistic three-dimensional feeling.

In order that the lines connecting the centers of the respective light emitting portions and the centers of the respective pixel regions corresponding to the respective light emitting portions can be arbitrarily made non-parallel to each other, the image display panel side must be used. Although it is possible to cope with this by changing the formation of each pixel region, it is possible to change the position of the light emitting unit within the plane of the light emitting unit or the light transmitting unit rather than adopting such a method. It is preferable to provide a light transmitting portion position changing means for changing the position in the plane. For example, the light source device is configured by a light emitting unit and a shutter unit that can form a plurality of dot-shaped light transmitting regions at predetermined positions,
The light emitting portion position changing means may change a light transmitting area in the shutter means. Also,
The light transmitting portion position changing means may be constituted by shutter means capable of forming a plurality of dot-shaped light transmitting areas at predetermined positions, and may be configured to change the light transmitting areas. Also,
The light source device is configured by arranging a plurality of point-shaped light emitting units in a plane, and the light emitting unit position changing unit changes the position of the light emitting unit by energizing a predetermined light emitting unit. Is also good. Further, the light source device may be constituted by a CRT, and the light emitting unit position changing means may change the position of the light emitting unit by controlling an electron gun and a deflection coil of the CRT.

[0015]

(Embodiment 1) Hereinafter, a three-dimensional image display device according to a first embodiment of the present invention will be described with reference to FIG.

FIG. 1 is a sectional view showing a three-dimensional image display device 1. The three-dimensional image display device 1 includes a light source device 2
And a transmissive liquid crystal display panel 3 provided on the light emission side of the light source device 2, and a liquid crystal display panel driving unit 4 for driving the liquid crystal display panel 3.

The light source device 2 comprises a backlight 21 and a pinhole array plate 22. Pinhole array plate 2
Reference numeral 2 denotes a plurality of pinholes 22a formed at predetermined intervals.
A group of rays is given.

The liquid crystal display panel driving section 4 supplies a pixel driving signal to the liquid crystal display panel 3 and a pixel area (for example, 9 to 2 pixels) including a plurality of pixels corresponding to each pinhole 22a.
0, composed of 3 to 20 vertical pixels) 3a. Each pixel in the pixel region 3a controls the amount of light transmitted (the amount of light transmitted by each of the R, G, and B pixels in the case of a color image) with respect to light rays in each direction from the corresponding pinhole 22a. The intensity is reproduced for the light rays in each direction. The liquid crystal display panel driving unit 4 is a liquid crystal display panel 3
Is generated using a computer (computer graphic technology). That is, a polygon object and a plurality of pinholes are virtually arranged on a computer, and each recording pixel area on a virtually provided recording surface located on a line connecting each point constituting the polygon object and the pinhole. Is calculated for each recording pixel (data for setting the amount of light transmission of a video display panel in a video display system), and a driving voltage is applied to each pixel based on this data.

The center of each pinhole 22a and each pixel region 3
The lines connecting to the center of a are not parallel to each other, and in this embodiment, the lines are set to intersect at a point corresponding to a standard distance between the image display panel 3 and the observer Z. I have. Here, the horizontal pitch between the centers of the pinholes 22a is A, the horizontal pitch between the centers of the pixel regions 3a is B, the distance between the liquid crystal display panel 3 and the pinhole array plate 22 is C,
Assuming that the standard distance between the liquid crystal display panel 3 and the observer Z is D, a relationship of A × D = B (D + C) is established. For example, the standard distance is empirically obtained. ,
The distance between the liquid crystal display panel 3 and the pinhole array plate 22 is determined in consideration of the required spread of light rays and the like.
Also, regarding the horizontal pitch between the centers of the pixel regions 3a,
The horizontal pitch between the centers of the pinholes 22a can be set by determining the resolution of the liquid crystal display panel 3 and the like and substituting these values into the above equation. Pinhole 2
The vertical pitch between the centers of 2a can be set similarly.

In the three-dimensional image display device having the configuration shown in FIG. 1, a line connecting the center of each pinhole 22a and the center of each pixel region 3a is a standard line between the image display panel 3 and the observer Z. Since the light beams intersect at a single point corresponding to the distance, light rays efficiently converge at a standard observation position, and the transition of the appearance of the image when the observer Z moves his / her head becomes smoother, thereby realizing a more realistic feeling. This makes it possible for the observer Z to recognize a certain three-dimensional feeling.

In the light source device 2, a light emitting means such as a metal halide lamp can be used in place of the backlight 21, and a structure in which the pinhole array plate 22 is unnecessary, for example, a light emitting diode or the like is arranged in an array. Or a CRT (cathode ray tube) can be used.

(Embodiment 2) Hereinafter, a three-dimensional image display device according to a second embodiment of the present invention will be described with reference to FIGS. For convenience of description, the same components as those described in the first embodiment are denoted by the same reference numerals.

FIG. 2A is a cross-sectional view showing the three-dimensional image display device 11, and FIG. The three-dimensional image display device 11 includes a light source device 5, a transmissive liquid crystal display panel 3 provided on the light emission side of the light source device 5, a liquid crystal display panel driving unit 4 that drives the liquid crystal display panel 3, It comprises.

The light source device 5 comprises a backlight 21 and a pinhole array plate 23. Pinhole array plate 2
Reference numeral 3 denotes a plurality of pinholes 23a formed at a predetermined interval.
A group of rays is given.

The liquid crystal display panel driving section 4 supplies a pixel driving signal to the liquid crystal display panel 3 to form a pixel region 3a composed of a plurality of pixels corresponding to each pinhole 23a. Each pixel in the pixel region 3a controls the amount of light transmitted from the corresponding pinhole 23a with respect to the light in each direction, whereby the intensity of the light in each direction is reproduced.

The center of each pinhole 23a and each pixel region 3
The lines connecting to the center of a are not parallel to each other, and in this embodiment, each line is a region E where the object is to be reproduced.
Is set to concentrate on The region where the object is to be reproduced is a position where the object is viewed as if there is an object, and in the case of creating an image using the above-described computer graphic technology, the region is arranged on virtually set coordinates. Can be said to be the coordinate position of the polygon object.

The three-dimensional image display device 1 having the configuration shown in FIG.
If 1, the center of each pinhole 23a and each pixel region 3
Since the line connecting the center of a is set to be concentrated in the area E where the object is to be reproduced, the number of light rays representing the object existing in the area E increases (this will be described later). Described below), the visible area of the object is increased (it becomes more wraparound), and the observer can recognize a more realistic three-dimensional feeling.

Here, for example, as shown in FIG. 3A, in a three-dimensional image display device having a conventional structure (a pinhole is represented by a square figure), a light ray representing a point e in an area E is of light rays l ₁ to l ₄ described present 4 in the figure, light l ₁
The three ~l _3. On the other hand, as shown in FIG.
In the three-dimensional image display device 11 of this embodiment (the pinhole is represented by a circle), the light rays representing the point e of the area E are all of the light rays L _{1 to} L ₄ described in the figure.
It can be seen that the number of rays has increased. The image displayed on the liquid crystal display panel 3 is preferably created in consideration of making the line connecting the center of each pinhole 23a and the center of each pixel region 3a non-parallel.

(Embodiment 3) Hereinafter, a three-dimensional image display apparatus according to a third embodiment of the present invention will be described with reference to FIGS. For convenience of description, the same components as those described in the first embodiment are denoted by the same reference numerals.

FIG. 4A is a cross-sectional view showing the three-dimensional image display device 12, and FIG. The three-dimensional image display device 12 includes a light source device 6, a transmissive liquid crystal display panel 3 provided on the light emission side of the light source device 6, a liquid crystal display panel driving unit 4 that drives the liquid crystal display panel 3, , A liquid crystal shutter drive unit 7.

The light source device 6 comprises a backlight 21 and a liquid crystal shutter 24 capable of arbitrarily forming a point-like light transmitting area at a predetermined position. The liquid crystal shutter 24 includes, for example, as shown in FIG.
a, or the light transmission region 24b represented by a dotted line. In addition, other light transmitting regions, for example, light transmitting regions (not shown, in which lines connecting the center of each light transmitting region and the center of each pixel region 3a corresponding to each light transmitting region are parallel to each other, This is referred to as a light transmission region 24c). The liquid crystal shutter drive unit 7 forms a light transmitting area by giving a drive signal to the liquid crystal shutter 24.

[0032] Here, the pitch of the light transmitting region 24a is wider than the pitch of the light transmitting area 24c, as shown in FIG. 4 (b), it serves to concentrate the light in the region E ₁ of the screen front side next, the pitch of the light transmissive region 24b is Yes made narrower than the pitch of the light transmission region 24c, so that the function to focus the light beam in the region E ₂ of the screen back side. That is, the three-dimensional image display device 12 of this embodiment can arbitrarily make the lines connecting the center of each light emitting portion and the center of each pixel region corresponding to each light emitting portion non-parallel to each other. And the area where the object is to be reproduced is the area E
When it is _1, to form a light transmitting region 24a by concentrating light in the region E _1, when the region to be reproduced object is a region E ₂ are areas the light beam to form a light transmitting area 24b E ₂ You can focus on

The area where the object is to be reproduced is, as described above, a position where the object appears to be present, and is virtually set if an image is created using computer graphic technology. It can be said that this is the coordinate position of the polygon object placed on the coordinate set, and the CPU (not shown) gives a command signal to the liquid crystal shutter drive unit 7 based on the position information of this polygon object, so that the light transmitting area is Can be changed in accordance with the position of. The image displayed on the liquid crystal display panel 3 is preferably created in consideration of making the line connecting the center of the light transmission area of the liquid crystal shutter 24 and the center of each pixel area 3a non-parallel.

Although the backlight 21 is used in the light source device in the above embodiment, a metal halide lamp or the like may be used. The light source device is a backlight 2
1 and the liquid crystal shutter 22, it is possible to form a point-like light emitting portion for giving a divergent light beam at an arbitrary position without using such a structure. For example, FIG.
As shown in (a), a CRT (cathode ray tube) 25 is used as a light source, and an electron gun (electron emission at a place to emit light) and a deflection coil (movement of electrons to a place to emit light) of the CRT. , The position of the light emitting unit can be changed. Further, as shown in FIG. 6B, a plurality of point-like light-emitting means (for example, light-emitting diodes) 26 are arranged in a plane, and a first light-emitting group of the light-emitting means 26 (shown by a solid line in the figure). ) And the second light-emitting group (indicated by a dotted line in the figure) may be arranged at different pitches, and power may be selectively supplied to each group. Further, in FIGS. 5 and 6 (b), the pitch of the light emitting portions is changed only in the horizontal direction. However, the present invention is not limited to this, and the pitch of the light emitting portions may be changed in the vertical direction. It is.

In the above-described example, the configuration corresponding to the three-dimensional image display apparatus of the light beam reproducing system in which the image display panel is disposed in front of the point light source has been described. However, a pinhole is provided in front of the image display panel. The configurations described in the above-described first to third embodiments can be applied to a three-dimensional image display device of a light beam reproduction system in which an array plate or the like is arranged.

That is, an image display panel for displaying an image, and light transmitting portions into which image light from the image display panel is incident are arranged at predetermined intervals in a plane, and a light group corresponding to scattered light from an object is formed. A point light transmitting portion forming panel to be given;
Display panel driving means for setting a display image to be displayed in each pixel region of the image display panel corresponding to each light transmitting portion,
In the three-dimensional image display device provided with, the lines connecting the centers of the respective light transmitting portions and the centers of the respective pixel regions corresponding to the respective light transmitting portions may be set to be non-parallel to each other. Then, a line connecting the center of each light transmitting portion and the center of each pixel region corresponding to each light transmitting portion may intersect at a position corresponding to a standard distance between the video display panel and the observer. Alternatively, a line connecting the center of each light transmitting portion and the center of each pixel region corresponding to each light transmitting portion may be configured to be concentrated in a region where an object is to be reproduced.

Similarly, an image display panel for displaying an image and a light transmitting portion on which image light from the image display panel is incident are arranged at predetermined intervals in a plane, and correspond to scattered light from an object. A three-dimensional image display comprising: a point light transmitting portion forming panel for providing a light beam group; and display panel driving means for setting a display image to be displayed in each pixel region of the image display panel corresponding to each light transmitting portion. In the apparatus, a line connecting the center of each light transmitting portion and the center of each pixel region corresponding to each light transmitting portion may be arbitrarily non-parallel to each other. Then, a line connecting the center of each light transmitting portion and the center of each pixel region corresponding to each light transmitting portion may be concentrated in the region according to the region in which the object is to be reproduced. In such a configuration, a light transmitting unit position changing unit that changes the position of the light transmitting unit in the plane is used. The light transmitting portion position changing means may be configured to change the light transmitting portion by using shutter means capable of forming a plurality of dot-shaped light transmitting regions at predetermined positions. Specifically, it can be configured using the liquid crystal shutter 24 and the liquid crystal shutter drive unit 7 in FIG.

In such a configuration in which a pinhole array plate or the like is disposed in front of the image display panel, the image display panel includes a transmissive liquid crystal display panel (requires a backlight) and a self-luminous type. Video display panel (LE
D display, organic EL display, plasma display, etc.) can be used.

[0039]

As described above, according to the present invention, the center of each point-like light emitting portion or each pinhole that gives a group of light rays corresponding to the scattered light from the object, and each light emitting portion or each pin Lines connecting the centers of the respective pixel regions corresponding to the holes are set non-parallel to each other, and in particular, the center of each light emitting portion or each pinhole and each pixel corresponding to each light emitting portion or each pinhole. In a configuration in which the line connecting the center of the region intersects at a position corresponding to the standard distance between the image display panel and the observer, light rays efficiently gather at the standard observation position, and the observer turns the head. The transition of the appearance of the image when the image is moved becomes smooth, so that the observer can recognize a more realistic three-dimensional feeling. Further, a line connecting the center of each light emitting portion or each pinhole and the center of each pixel region corresponding to each light emitting portion or each pinhole is concentrated in a region where an object is to be reproduced. Then, the number of light rays representing the object existing in the area increases, the area where the object can be seen increases, and the observer can recognize a more realistic three-dimensional feeling.

Further, according to the present invention, each dot-like light emitting portion or the center of each pinhole for providing a light beam group corresponding to the scattered light from the object and each pixel corresponding to each light emitting portion or each pinhole are provided. The line connecting the center of the region is set to be arbitrarily non-parallel to each other.
The line connecting the center of each light emitting portion or each pinhole and the center of each pixel region corresponding to each light emitting portion or each pinhole is concentrated on the region according to the region where the object is to be reproduced. In the configuration described above, even if the area in which the object is to be reproduced changes, the number of light rays representing the object can be increased in the changed area, the area where the object can be seen increases, and a more realistic tertiary The original feeling can be recognized by the observer.

[Brief description of the drawings]

FIG. 1 is a perspective view showing a schematic configuration of a three-dimensional image display device according to a first embodiment of the present invention.

FIG. 2A is a cross-sectional view showing a three-dimensional image display device according to a second embodiment, and FIG. 2B is an operation explanatory diagram.

FIG. 3 (a) is an operation explanatory view of a conventional configuration for comparison with the present invention, and FIG. 3 (b) is an operation explanatory view of a three-dimensional image display device of a second embodiment. .

FIG. 4A is a cross-sectional view showing a three-dimensional image display device according to a third embodiment, and FIG. 4B is an operation explanatory diagram.

FIG. 5 is a perspective view showing an example of a change in the position of a light emitting unit by the liquid crystal shutter having the configuration of FIG.

FIGS. 6A and 6B are perspective views each showing a light source device which can be used in place of the light source device shown in the configuration of FIG.

FIG. 7 is a cross-sectional view showing a conventional three-dimensional image display device, and FIG. 7B is an operation explanatory view.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 3D image display device 2 light source device 22 pinhole array plate 22 a pinhole 3 liquid crystal display panel 3 a pixel area 4 liquid crystal display panel drive unit 11 3D image display device 5 light source device 23 pinhole array plate 23 a pinhole 12 3D Image display device 6 Light source device 24 Liquid crystal shutter

 ──────────────────────────────────────────────────続 き Continued on the front page F term (reference) 2H088 EA05 HA28 KA30 MA06 2H091 FA23Z FA31Z FA41Z FA44Z FA45Z FA50Z GA11 KA10 LA16 MA01 5C061 AA06 AA21 AB17

Claims (12)

[Claims] 1. A light source device in which point-like light emitting portions for providing a light beam group corresponding to scattered light from an object are arranged in a plane at predetermined intervals, and an image arranged on a light emitting side of the light source device. In a three-dimensional image display device including: a display panel; and a display panel driving unit that sets a display image to be displayed in each pixel region of the image display panel corresponding to each light emitting unit. A line connecting the center of each pixel region corresponding to each of the light emitting units is set to be non-parallel to each other. 2. An image display panel for displaying an image, and a light transmitting portion on which image light from the image display panel is incident are arranged in a plane at predetermined intervals, and a light group corresponding to scattered light from an object is formed. A three-dimensional image display device comprising: a point light transmitting portion forming panel to be provided; and display panel driving means for setting a display image to be displayed in each pixel region of the image display panel corresponding to each light transmitting portion. A three-dimensional image display device, wherein lines connecting the center of each light transmitting portion and the center of each pixel region corresponding to each light transmitting portion are set non-parallel to each other. 3. The three-dimensional image display device according to claim 1, wherein a center of each light emitting portion or each light transmitting portion and each pixel region corresponding to each light emitting portion or each light transmitting portion. A line connecting the center of the three-dimensional image and the observer intersects at a position corresponding to a standard distance between the image display panel and the observer. 4. The three-dimensional image display device according to claim 1, wherein a center of each light emitting portion or each light transmitting portion and each pixel region corresponding to each light emitting portion or each light transmitting portion. A line connecting the center of the three-dimensional image to a region where the object is to be reproduced. 5. A light source device in which point-like light emitting portions that provide a group of light rays corresponding to scattered light from an object are arranged in a plane at predetermined intervals, and an image arranged on the light emitting side of the light source device. In a three-dimensional image display device including: a display panel; and a display panel driving unit that sets a display image to be displayed in each pixel region of the image display panel corresponding to each light emitting unit. A three-dimensional image display device which is set so that lines connecting the center of each pixel region corresponding to each of the light emitting units can be arbitrarily set to be non-parallel to each other. 6. An image display panel for displaying an image, and a light transmitting portion into which image light from the image display panel is incident is disposed at a predetermined interval in a plane, and a light group corresponding to scattered light from an object is formed. A three-dimensional image display device comprising: a point light transmitting portion forming panel to be provided; and display panel driving means for setting a display image to be displayed in each pixel region of the image display panel corresponding to each light transmitting portion. A three-dimensional image display device, wherein a line connecting the center of each light transmitting portion and the center of each pixel region corresponding to each light transmitting portion is set to be arbitrarily non-parallel to each other. . 7. The three-dimensional image display device according to claim 5, wherein a center of each light emitting unit or each light transmitting unit and each pixel area corresponding to each light emitting unit or each light transmitting unit. A line connecting the center of the three-dimensional image and the center of the three-dimensional image display device. 8. The three-dimensional image display device according to claim 5, wherein the position of the light emitting unit is changed or the position of the light transmitting unit changes the position of the light emitting unit within the plane. A three-dimensional image display device comprising a light transmitting portion position changing means for changing the position of the light transmitting portion within the plane. 9. The three-dimensional image display device according to claim 8, wherein the light source device includes a light emitting unit and a shutter unit capable of forming a plurality of dot-shaped light transmitting regions at predetermined positions. The three-dimensional image display device, wherein the unit position changing means is configured to change a light transmitting area in the shutter means. 10. The three-dimensional image display device according to claim 8, wherein the light transmitting part position changing means comprises shutter means capable of forming a plurality of dot-shaped light transmitting areas at predetermined positions, A three-dimensional image display device, wherein the three-dimensional image display device is configured to change the number of images. 11. The three-dimensional image display device according to claim 8, wherein the light source device includes a plurality of point-like light emitting units arranged in a plane, and the light emitting unit position changing unit includes a predetermined light emitting unit. A three-dimensional image display device characterized in that the position of the light emitting unit is changed by energizing. 12. The three-dimensional image display device according to claim 8, wherein the light source device comprises a CRT, and the light emitting unit position changing means controls an electron gun and a deflection coil of the CRT to control the light emitting unit. A three-dimensional image display device configured to change a position.