JP3658311B2 - Three-dimensional display method and apparatus - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a three-dimensional display method and apparatus, and more particularly, to a three-dimensional display method and apparatus capable of electronically reproducing a three-dimensional image with a reduced amount of information.
[0002]
[Prior art]
A liquid crystal shutter glasses method shown in FIG. 27 is well known as a conventional device that can be electrically rewritten, has a small amount of information, and enables stereoscopic display of moving images.
Hereinafter, the principle of the liquid crystal shutter glasses method will be described.
In this liquid crystal shutter glasses method, a camera (702, 703) captures a three-dimensional object 701 from different directions, and generates an image (parallax image) obtained by capturing the three-dimensional object 701 from different directions.
Images taken by the cameras (702, 703) are combined by a video signal conversion device 704 into one video signal and input to a two-dimensional display device (for example, a CRT display device) 705.
The observer 707 observes the image of the two-dimensional display device 705 through the liquid crystal shutter glasses 706.
Here, when the two-dimensional display device 705 displays an image of the camera 703, the liquid crystal shutter glasses 706 are in a non-transparent state on the left side and a transmissive state on the right side, and the image of the camera 702 is displayed on the two-dimensional display device 705. Is displayed, the left side of the liquid crystal shutter glasses 706 is transmissive and the right side is non-transmissive.
When the operation is switched at high speed, it feels like a parallax image is visible to both eyes due to the afterimage effect of the eyes. Accordingly, stereoscopic viewing with binocular parallax is possible.
[0003]
Further, as a conventional device that can be electrically rewritten, has a small amount of information, and enables stereoscopic display of a moving image, a volume type method shown in FIG. 28 has been proposed.
Hereinafter, the principle of the volume type method will be described.
In this volume type method, as shown in FIG. 28 (b), a three-dimensional object 711 is sampled in the depth direction as viewed from the observer to form a two-dimensional image collection 712, and this two-dimensional image collection 712 is Using the volume type three-dimensional display device 713 shown in FIG. 28A, for example, the three-dimensional redevelopment 714 is reconfigured by arranging again in the depth direction by time division.
[0004]
[Problems to be solved by the invention]
However, the liquid crystal shutter glasses method shown in FIG. 27 requires the liquid crystal shutter glasses 706, and thus has a problem that it is very unnatural in a video conference.
In addition, among the physiological factors of stereoscopic vision, a large contradiction occurs between binocular parallax, convergence, and focus adjustment.
That is, in the liquid crystal shutter glasses system shown in FIG. 27, binocular parallax and convergence are almost satisfactory, but the focus surface is on the display surface.
In the volume type method shown in FIG. 28, since the depth position of the three-dimensional object 711 to be reproduced is close to and sandwiched between the surface on which the image is actually displayed, the liquid crystal shutter shown in FIG. Unlike the spectacle method, it is possible to suppress inconsistencies between binocular parallax, convergence, and focus adjustment.
However, this volume type method has a problem in that it is difficult to reproduce a three-dimensional object at a middle position or a three-dimensional object greatly changing in the depth direction because the positions are discrete in the depth direction. there were.
[0005]
The present invention has been made to solve the above-described problems of the prior art, and an object of the present invention is to eliminate the contradiction between physiological factors of stereoscopic vision without glasses, and further It is an object of the present invention to provide a three-dimensional display method and apparatus that can be rewritten and capable of displaying moving images.
The above and other objects and novel features of the present invention will become apparent from the description of this specification and the accompanying drawings.
[0006]
[Means for Solving the Problems]
Of the inventions disclosed in this application, the outline of typical ones will be briefly described as follows.
That is, the present invention generates a two-dimensional image obtained by projecting a display target object from a viewing direction of an observer on a plurality of display surfaces arranged at different depth positions as viewed from the observer. A two-dimensional image is displayed on each of two arbitrary display surfaces of the plurality of display surfaces, and the luminance of the displayed two-dimensional image is determined for each of the two arbitrary display surfaces of the plurality of display surfaces. Is a three-dimensional display method for generating a three-dimensional stereoscopic image by independently changing Polarization direction of incident light disposed between (n + 1) polarization type bifocal lenses having different focal lengths with respect to two independent polarization directions and the (n + 1) polarization type bifocal lenses. Is composed of n polarization switching units that convert the polarization direction into one of the two independent polarization directions. A polarization-type multifocal optical system can be used to Separating the display light into the two independent polarization directions, and for each of the two independent polarization directions. The display light is imaged on any two display surfaces of the plurality of display surfaces, The polarization direction of the n polarization switching devices is switched in synchronization with a two-dimensional image formed on any two display surfaces of the plurality of display surfaces, and The polarization direction of the display light is controlled, and the brightness of the two-dimensional image formed on any two display surfaces of the plurality of display surfaces is independently changed.
[0007]
In a preferred embodiment of the present invention, when the depth position of the display target object is a position close to the observer, an image is formed on a display surface close to the observer among the two display surfaces. The polarization direction of the display light is controlled so that the brightness of the two-dimensional image formed on the display surface far from the observer among the two display surfaces is low, and the display light is controlled. When the depth position of the target object is a position far from the observer, the luminance of the two-dimensional image formed on the display surface close to the observer among the two display surfaces is low, and the two The polarization direction of the display light is controlled so that the luminance of a two-dimensional image formed on the display surface of the display surface far from the observer is high.
In a preferred embodiment of the present invention, the two-dimensional image is sequentially switched within the afterimage time of the human eye, and the display light of each two-dimensional image is sequentially displayed on any two of the plurality of display surfaces. A three-dimensional moving image is generated by forming an image on a surface.
In a preferred embodiment of the present invention, when the depth position of each part of the two-dimensional image is a position close to the observer, an image is formed on a display surface close to the observer among the two display surfaces. Two-dimensional image Of each part A two-dimensional image formed on a display surface having a high brightness and distant from the observer among the two display surfaces. Of each part When the luminance is low and the depth position of each part of the two-dimensional image is a position far from the observer, the two images are formed on the display surface close to the observer. Dimensional image Of each part The luminance of the two-dimensional image formed on the display surface far from the observer is low among the two display surfaces. Of each part The polarization direction of the display light is controlled for each part of the two-dimensional image so as to increase the luminance.
[0008]
The present invention also provides a two-dimensional image display means for displaying a two-dimensional image, a polarization variable means for controlling the polarization direction of the display light of the two-dimensional image incident from the two-dimensional image display means, The display light emitted from the polarization variable means is separated into two independent polarization directions, and the display light for each of the two independent polarization directions is arranged at different depth positions as viewed from the observer. A polarization-type multifocal optical system that forms an image on any two display surfaces of the display surface and a synchronization device, and forms an image on any two display surfaces of the plurality of display surfaces The two-dimensional image display means, the polarization variable means, and the polarization-type multifocal optical system are arranged so that each two-dimensional image is a two-dimensional image that overlaps on the observer's line of sight and has a different depth position. The polarization type multifocal optical system is the two-dimensional display device. The (n + 1) polarization type bifocal lenses having different focal lengths with respect to the vertical polarization direction and the (n + 1) polarization type bifocal lenses, the polarization direction of the incident light, And n polarization switching units that convert the polarization direction to one of the two independent polarization directions, and the synchronization device is connected to any two display surfaces of the plurality of display surfaces. The polarization direction of the n polarization switchers is switched in synchronization with the two-dimensional image to be imaged. In addition, the polarization direction of the display light of the two-dimensional image from the two-dimensional image display means emitted from the polarization variable means is controlled to form an image on any two display surfaces of the plurality of display surfaces. Independently change the brightness of the two-dimensional image It is characterized by that.
[0009]
In a preferred embodiment of the present invention, when the depth of the display target object is a position close to the observer, the polarization varying means has a display surface close to the observer among the two display surfaces. The two-dimensional image display means so that the luminance of the two-dimensional image formed on the display surface is high and the luminance of the two-dimensional image formed on the display surface far from the observer among the two display surfaces is low. When the polarization direction of the display light of the two-dimensional image incident from is controlled and the depth position of the display target object is a position far from the observer, the two display surfaces are close to the observer The two-dimensional image is formed so that the luminance of the two-dimensional image formed on the display surface is low and the luminance of the two-dimensional image formed on the display surface far from the observer among the two display surfaces is high. Controlling the polarization direction of the display light of the two-dimensional image incident from the display means To.
In a preferred embodiment of the present invention, the polarization variable means changes the display light of the two-dimensional image incident from the two-dimensional image display means to elliptically polarized light.
In a preferred embodiment of the present invention, the polarization varying means converts the two-dimensional image display light incident from the two-dimensional image display means into the two independent polarization directions or the two independent polarization directions. It is characterized in that it is changed to linearly polarized light at an intermediate angle.
[0010]
In a preferred embodiment of the present invention, the polarization variable means includes a liquid crystal.
In a preferred embodiment of the present invention, the two-dimensional image display means has a plurality of pixels, and the polarization variable means has a plurality of polarization variable elements, and each polarization variable element of the polarization variable means Is characterized by controlling the polarization of display light of one or a plurality of pixels of the two-dimensional image display means.
In a preferred embodiment of the present invention, the polarizing bifocal lens has a fixed refractive index. Fixed focus lens A region and a birefringent medium having birefringence are included.
In a preferred embodiment of the present invention, The polarizing bifocal lens has a lens shape or prism on one side or both sides. A birefringent medium having a shape is included.
In a preferred embodiment of the present invention, the birefringent medium is a liquid crystal, calcite, litimi niobate, polymer, calcite or litimi niobate optically bonded, or uniaxially stretched or 2 It includes a laminate of a plurality of axially stretched polymer thin films.
[0011]
In a preferred embodiment of the present invention, the polarizing bifocal lens includes first and second optical systems having different optical characteristic values, and incident light in one polarization direction of the two independent polarization directions. Is incident on the first optical system, the other is incident on the second optical system, and the first polarization beam splitter is combined with the light that has passed through the first optical system and the second optical system. 2 polarization beam splitters.
In a preferred embodiment of the present invention, the polarizing bifocal lens has different optical characteristic values. First and second An optical system; a first beam splitter for separating incident light into two light; and First A first polarizing plate on which one light separated by a beam splitter is incident, and light in one of the two independent polarization directions is incident on the first optical system;
Said First A second polarizing plate on which the other light separated by the beam splitter is incident and light in the other polarization direction of the two independent polarization directions is incident on the second optical system; and the first optical system And a second beam splitter that synthesizes the light that has passed through the second optical system.
In a preferred embodiment of the present invention, the polarization switch includes a liquid crystal.
[0012]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
Note that components having the same function are denoted by the same reference symbols throughout the drawings for describing the embodiment, and the repetitive description thereof will be omitted.
[Embodiment 1]
The three-dimensional display device according to Embodiment 1 of the present invention is a three-dimensional display device that expresses the entire depth of a three-dimensional object that is a display target object.
[Outline of 3D Display Device as Basic of Embodiment of Present Invention]
FIG. 2 is a diagram showing a schematic configuration of the three-dimensional display device that is the basis of the first embodiment of the present invention.
The three-dimensional display device shown in FIG. 2 includes a two-dimensional display device 100, a polarization variable device 130, and a polarization type bifocal lens 131.
[0013]
In the three-dimensional display device shown in FIG. 2, the display light of the two-dimensional image displayed on the two-dimensional display device 100 is imaged in two directions by the polarization type bifocal lens 131 according to the polarization direction of emission from the polarization variable device 130. It is separated and displayed on the plane (image plane 203 and image plane 204 in FIG. 2) with a luminance ratio corresponding to the polarization direction.
For example, when the polarization direction emitted from the polarization variable device 130 coincides with one of the intrinsic polarization directions (meaning two independent polarization directions) in the polarization type bifocal lens 131, for example, the imaging plane When a two-dimensional image displayed on the two-dimensional display device 100 is formed on the 203 and the output polarization direction coincides with the other intrinsic polarization direction, for example, the two-dimensional display device 100 is formed on the image plane 204. A displayed two-dimensional image is formed.
In the case of other polarization directions (including linearly polarized light, circularly polarized light, elliptically polarized light, etc.), the respective luminances on the imaging surface 203 and the imaging surface 204 are, for example, the projection of the outgoing polarization direction to the intrinsic polarization direction. Separated by component ratio.
[0014]
Here, as the two-dimensional display device 100, for example, a CRT display device, a liquid crystal display, an LED display, a plasma display, an FED display, a projection display, or a line drawing display can be used.
As the polarization variable device 130, for example, a device using liquid crystal or a device using PLZT which has birefringence and whose birefringence can be controlled by an electric field can be used. These devices will be described later.
Furthermore, as the polarizing bifocal lens 131, for example, as a birefringent medium described later, for example, a birefringent crystal such as liquid crystal, calcite, or lithium niobate, an apparatus using a stretched polymer, or a polarizing beam splitter The apparatus includes two optical systems having different imaging planes, or an apparatus including a beam splitter and a polarizing plate and two optical systems having different imaging planes. These devices will be described later.
[0015]
The basic operation of the 3D display device shown in FIG. 2 will be described below.
In the three-dimensional display device shown in FIG. 2, as shown in FIG. 3, for example, a three-dimensional object (display target object) 106 that is desired to be presented to the observer 10 is imaged from the viewing direction of both eyes of the observer 10. An image (hereinafter referred to as “2D image”) 107 projected onto the surfaces (203, 204) is generated and displayed on the two-dimensional display device 100 shown in FIG.
Here, as a method of generating the 2D image 107, a method using a two-dimensional image obtained by photographing the three-dimensional object 106 from the direction of the line of sight, a method of combining from a plurality of two-dimensional images taken from different directions, or Various methods such as a synthesis technique using computer graphics and a method using modeling can be employed.
[0016]
One polarization variable element of the polarization variable device 130 is made to correspond to one or a plurality of pixel groups of the two-dimensional display device 100.
For example, as shown in FIG. 4, one polarization variable element 150 of the polarization variable device 130 is made to correspond to one pixel 140 of the two-dimensional display device 100, or, for example, as shown in FIG. One polarization variable element 151 of the polarization variable device 130 is made to correspond to the plurality of pixels 141 of the two-dimensional display device 100.
Next, the output polarization direction of the polarization variable element (for example, 150 in FIG. 4 and 151 in FIG. 5) of the polarization variable device 130 is set to one pixel (for example, 140 in FIG. 4) or a plurality of pixels. Are changed corresponding to the depth position of the part of the three-dimensional object 106 corresponding to the pixel (for example, 141 in FIG. 5).
As a result, images (two-dimensional images) having respective luminances corresponding to the outgoing polarization direction are displayed on the imaging plane 203 and the imaging plane 204.
[0017]
However, the positional relationship of the imaging planes (203, 204) is adjusted in advance using an appropriate optical system so that the images of the imaging plane 203 and the imaging plane 204 overlap on the line of sight of the observer 10.
The images of the image formation surface 203 and the image formation surface 204 can be overlapped on the line of sight of the observer 10, for example, by arranging the center and the center of gravity of each 2D image 107 on the line of sight. is there.
The main point of the three-dimensional display device of the present embodiment is that the luminance of each part of the image on the imaging plane 203 and the imaging plane 204 is changed by using the polarization variable device 130 to change the outgoing polarization direction of each polarization variable element. Is changed corresponding to the depth position of the three-dimensional object 106 while keeping the overall luminance viewed from the observer 10 constant.
[0018]
An example of how to change this will be described below with reference to FIGS.
Here, it is assumed that the imaging plane 203 is closer to the viewer 10 than the imaging plane 204, and the intrinsic polarization directions of the polarization type bifocal lens 131 corresponding to the imaging planes (203, 204) are p direction, s direction.
In FIG. 6 to FIG. 9, dark portions represent high luminance portions.
For example, as shown in FIG. 6, when the output polarization direction of each polarization variable element of the polarization variable device 130 is matched with the p direction, the luminance of the image on the imaging plane 203 becomes equal to the luminance of the three-dimensional object 106, and The brightness of the image on the imaging plane 204 becomes zero, and the case where the three-dimensional object 106 is on the imaging plane 203 can be expressed.
Next, for example, as shown in FIG. 7, when the outgoing polarization direction of each polarization variable element of the polarization variable device 130 is slightly tilted from the p direction, the brightness of the image on the imaging plane 203 decreases compared to FIG. 6. Further, the brightness of the image on the imaging plane 204 increases, and the case where the three-dimensional object 106 is slightly separated from the imaging plane 203 and approaches the imaging plane 204 side can be expressed.
[0019]
Further, for example, as shown in FIG. 8, when the outgoing polarization direction of each polarization variable element of the polarization variable device 130 is inclined with respect to the polarization shown in FIG. 7, the brightness of the image on the imaging plane 203 is further increased compared to FIG. Further, the brightness of the image on the imaging plane 204 is further increased, and the case where the three-dimensional object 106 is closer to the imaging plane 204 than the imaging plane 203 can be expressed.
Finally, for example, as shown in FIG. 9, when the outgoing polarization direction of each polarization variable element of the polarization variable device 130 matches the s direction, the luminance of the image on the imaging plane 204 becomes equal to the luminance of the three-dimensional object 106. Further, the brightness of the image on the imaging plane 203 becomes zero, and the case where the three-dimensional object 106 is on the imaging plane 204 can be expressed.
[0020]
According to the display method described above, even if it is the imaging plane (203, 204) that actually displays an image due to human physiological or psychological factors or illusions, it is as if the observer 10 It feels as if the three-dimensional object 106 is located in the middle.
The three-dimensional display device shown in FIG. 2 differs from the conventional three-dimensional display device shown in FIG. 27 in that there are at least two surfaces on which an image is actually displayed across the illusion position. It is considered that the contradiction between binocular parallax, convergence, and focus adjustment, which are problems in the conventional three-dimensional display device shown, can be greatly suppressed, and eye strain can be suppressed.
In addition, unlike the conventional three-dimensional display device shown in FIG. 28, a three-dimensional object that exists at an intermediate position on the image plane appears three-dimensionally to the observer, so that it is not a conventional three-dimensional effect. Have advantages.
Furthermore, since the three-dimensional display device shown in FIG. 2 can also represent a three-dimensional object between a plurality of surfaces, there is an advantage that the amount of data when performing three-dimensional display can be greatly reduced.
[0021]
In addition, since the 3D display device shown in FIG. 2 uses a human physiological or psychological factor or illusion based only on a change in the brightness of an image, a coherent light source such as a laser is not particularly required as a light source. In addition, there is an advantage that colorization is easy.
In addition, since the three-dimensional display device shown in FIG. 2 does not include a mechanical drive unit, it has an advantage that it is suitable for weight reduction and improved reliability.
The 3D display device shown in FIG. 2 has an advantage that the control is simple because the 2D display device 100 is responsible for the display in the 2D direction and the polarization variable device 130 is the representation in the depth direction.
Furthermore, it is possible to make a difference in each resolution and the like, and there is an advantage that the amount of information can be reduced. That is, in view of the fact that the resolution in the depth direction is lower than that in the two-dimensional direction, it is also effective to reduce the resolution in the depth direction.
[0022]
In the three-dimensional display device shown in FIG. 2, the size of the device is not necessarily restricted by the position, interval, size, etc. of the image plane.
In other words, the position of the imaging plane (203, 204) can be arranged on the entire surface of the apparatus as a real image surface by an optical system, for example, or can be arranged on the rear side of the apparatus by an optical system, for example. is there.
Also, the distance between the image planes (203, 204) can be made larger than that of the present apparatus by an optical system, for example.
Furthermore, the size of the image to be formed can also be made larger than that of the present apparatus by an optical system, for example.
For this reason, compared with the method of actually arrange | positioning a display apparatus, there also exists an advantage which can make the whole three-dimensional display apparatus compact.
[0023]
In the above description, the case where the luminance of the 2D image 107 displayed on the plurality of image planes (203, 204) is changed while keeping the overall luminance viewed from the observer constant has been described. Emphasizing the three-dimensional effect by gradually decreasing the overall luminance as viewed from the observer 10 is a technique often used in computer graphics, and this is also applied in the present embodiment. Obviously, the effect can be further enhanced by adoption.
In addition, the 2D image 107 is sequentially switched, and the polarization direction of the display light is sequentially switched for each of the 2D image 107 so that the display light of the 2D image 107 is displayed on the imaging plane (203, 204). A three-dimensional stereoscopic moving image can be generated.
Further, the three-dimensional display device shown in FIG. 2 only describes the basic configuration. For example, it is clear that aberrations can be reduced by adding an optical system to the three-dimensional display device.
Furthermore, in the three-dimensional display device shown in FIG. 2, the case where the observer 10 is located at the front position of the center of the three-dimensional display device has been mainly described. However, the observer 10 is located at another position. However, the effects described above can be easily obtained by changing or adding the optical system.
[0024]
[Features of the three-dimensional display device of the present embodiment]
The three-dimensional display device shown in FIG. 2 is provided with two imaging planes (203, 204) and displays a two-dimensional image on the two imaging planes (203, 204). The form of the three-dimensional display device is an embodiment in which a plurality of pairs of imaging planes are provided and a two-dimensional image is displayed on the plurality of pairs of imaging planes.
FIG. 1 is a diagram showing a schematic configuration of the three-dimensional display device according to Embodiment 1 of the present invention.
As shown in the figure, in the three-dimensional display device of the present embodiment, a multifocal optical device 104 capable of switching a plurality of focal lengths is arranged on the viewer 10 side of the polarization type bifocal lens 131, and 2 is different from the three-dimensional display device shown in FIG. 2 in that the focal length of the multifocal optical device 104 is switched, and the two-dimensional display device 100 and the synchronization device 105 for synchronizing the polarization variable device 130 are provided. .
The polarization type bifocal lens 131 and the multifocal optical device 104 constitute the polarization type multifocal optical system of the present invention.
The multifocal optical device 104 is configured to include a plurality of bifocal optical devices 113 each including a polarization switching device 111 and a polarization type bifocal lens 112 arranged optically in series.
FIG. 1 illustrates m bifocal optical devices (113 to 1m3) each including a polarization switch (111 to 1m1) and a polarization type bifocal lens (112 to 1m2).
[0025]
Here, the polarization switching device (111 to 1m1) is configured by, for example, a device using liquid crystal, which will be described later, or a device using birefringence and PLZT having birefringence that can be controlled by an electric field. Is done.
In the present embodiment, the principal axis directions perpendicular to the polarization directions in the polarization switching units (111 to 1m1) and the polarization type bifocal lenses (112 to 1m2), for example, the p direction and the s direction are matched.
The polarizing bifocal lens (112 to 1m2) is a bifocal lens having a focal length that differs depending on the polarization direction, for example, the p direction and the s direction, by a structure as described later.
For example, when the focal lengths of the polarizing bifocal lenses (112 to 1m2) are (fp1, fs1) to (fpm, fsm), respectively, the focal lengths (fp1, fs1) to the focal lengths (fpm, fsm). Are all different values.
[0026]
The operation of the three-dimensional display device of this embodiment will be described below.
First, the focal length switching operation in the multifocal optical device 104 of the present embodiment will be described.
Each polarization switch (111 to 1m1) has a function of switching between a mode in which the polarization direction of incident light is preserved and emitted and a mode in which the polarization direction is changed to a direction perpendicular to the polarization direction of incident light and emitted. .
Further, the polarization type bifocal lens (112 to 1m2) itself does not change the polarization direction.
Therefore, the polarization direction of the light incident on a certain polarization switch 1i1 (i = 1 to m) can be known from the operation state of the polarization switch (111 to 1j1; j = i-1) in the preceding stage of the polarization switch 1i1. Therefore, the polarization direction of the outgoing light from the polarization switch 1i1 can be uniquely selected.
Therefore, by switching the polarization direction of each polarization switching device (111 to 1m1), two focal lengths (fpi, fsi) (i = 1) of each polarization type bifocal lens (112 to 1m2) arranged immediately after that. ~ M) can be selected.
[0027]
For this reason, assuming that the focal lengths (fp1 to fpm, fs1 to fsm) are all different values, the combination of selectable (switchable) focal lengths in the polarization type bifocal lens (112 to 1m2) is 2 ^m There will be streets.
Considering that the overall focal length of the multifocal optical device 104 can be calculated from the respective focal lengths of the polarization type bifocal lenses (112 to 1m2), the overall focal length of the multifocal optical device 104 is 2. ^m You can change the street.
For example, the distance between the polarizing bifocal lenses (112 to 1m2) is negligibly small, and in the case of a paraxial system, as is well known in optics, the total focal length of the multifocal optical device 104 can be reduced. The reciprocal is the sum of the reciprocals of the focal lengths of the polarization bifocal lenses (112 to 1m2).
Of course, in general, the overall focal length of the multifocal optical device 104 should be calculated by the focal length and optical thickness of each polarization type bifocal lens (112-1m2) and the distance between them. That is well known.
As described above, in the multifocal optical device 104, a large number of focal lengths can be electrically switched by a combination of switching of the polarization direction of each polarization switch (111 to 1m1).
The image of the two-dimensional display device 100 arranged behind the multi-focal optical device 104 when viewed from the observer 10 is formed as, for example, a real image or a virtual image, as is clear from the optical principle, and the image formation position is By changing the focal length of the multifocal optical device 104, the depth can be changed.
[0028]
In the above description, the case where one light is incident on each bifocal optical device (113 to 1m3) has been described. However, the polarization direction from the polarization bifocal lens 131 is two in the p direction and the s direction, respectively. When light is incident, the two lights in each p direction and s direction are 2 ^m An image is formed on each imaging plane.
Therefore, in the present embodiment, as described above, the output polarization direction of the polarization variable element (for example, 150 in FIG. 4 and 151 in FIG. 5) of the polarization variable device 130 is set to one pixel of the two-dimensional display device 100 ( For example, 140 in FIG. 4) or a multi-focal point that is changed corresponding to the depth position of the part of the three-dimensional object 106 corresponding to a plurality of pixels (for example, 141 in FIG. 5) and synchronized with the polarization variable device 130. 2 consisting of (203-2m3, 204-2m4) by switching the focal length of the optical device 104. ^m Images (two-dimensional images) having respective luminances corresponding to the output polarization directions of the polarization variable device 130 can be displayed on any pair of imaging planes of the pair of imaging planes.
However, the positional relationship of the imaging planes (203-2m3, 204-2m4) is set to an appropriate optical system so that the images on the imaging planes (203-2m3, 204-2m4) overlap on the line of sight of the observer 10. Adjust in advance using.
As described above, this is possible by, for example, arranging the center and the center of gravity of each 2D image 107 on the line of sight.
[0029]
The main point of the 3D display device according to the present embodiment is that the synchronization device 105 is a 2D image 107 displayed on the 2D display device 100 and is synchronized with the 2D image 107 displayed on any pair of imaging planes. Then, by changing the focal length of the multifocal optical device 104, an arbitrary pair of imaging planes (for example, the imaging plane 203 and the imaging plane 204) in each imaging plane (203-2m3, 204-2m4). In addition, a 2D image 107 displayed on the two-dimensional display device 100 is formed and, as described above, the polarization variable device 130 changes the outgoing polarization direction of each polarization variable element, thereby allowing any pair of connections. The brightness of each part of the 2D image 107 on the image plane is changed in accordance with the depth position of the three-dimensional object 106 while keeping the overall brightness as viewed from the observer 10 constant.
Accordingly, it is felt that the three-dimensional object 106 is located on any pair of imaging planes or in the middle due to human physiological or psychological factors or illusions.
[0030]
Thus, in the present embodiment, the 2D image 107 is displayed on the two-dimensional display device 100 one after another in a time division manner, and the focal length of the multifocal optical device 104 is synchronized with the display by the synchronization device 105. By changing, the three-dimensional stereoscopic image 106 can be displayed in a time division manner between a plurality of pairs of image planes or between a plurality of pairs of image planes.
Moreover, if these are performed at a high speed within the afterimage time of the human eye, for example, within 1/30 seconds, they are visible to the human almost simultaneously, so that the human can see the three-dimensional object.
Of course, it is obvious that the same can be realized by synchronizing the display of the two-dimensional display device 100 with the change in the focal length of the multifocal optical device 104.
Also in the 3D display method according to the present invention, as described above, a 3D stereoscopic image can be reproduced at substantially the same depth position as the 3D object 106, so that unlike conventional methods, binocular parallax, which is a physiological factor of humans, Convergence, focus adjustment, motion parallax can be almost satisfied, and natural stereoscopic vision with less fatigue can be realized.
[0031]
In the present invention, it is necessary to change the focal length within the afterimage time of the human eye, for example, within 1/30 second. In the present invention, the focal length is changed by the polarization switch (111 to 1m1). ), It is performed by accumulating binary operations only by switching the polarization direction. Thus, there is an advantage that the speed can be sufficiently increased.
Furthermore, in the present invention, the polarization type bifocal lens (112-1m2) responsible for the optical operation of the lens (lens power) is a static element, and the focal length can be changed only by switching the polarization. This has the advantage that elements that lower the resolution such as optical non-uniformity and scattering components can be suppressed.
Further, in the present invention, it is not a polarization type bifocal lens (112-1m2) having a more complicated boundary but a polarization switch (111-1m1) mainly having a parallel plate structure that functions by applying a voltage. Therefore, it is easy to manufacture and is advantageous in terms of reliability.
Further, in the present invention, a group of a plurality of polarization type bifocal lenses (112 to 1m2) fulfills one lens function, so that there is an advantage that the change in focal length can be greatly increased as compared with the conventional method.
[0032]
Also in the present embodiment, the 2D image 107 displayed on the two-dimensional display device 100 is sequentially switched, and the focal length of the multifocal optical device 104 is synchronized with the switching of the 2D image 107 by the synchronization device 105. The 2D image 107 is sequentially displayed on each pair of image planes (203-2m3, 204-2m4), and the polarization variable device 130 sequentially switches the 2D image 107 in each polarization variable element. By changing the outgoing polarization direction, it is possible to generate a three-dimensional stereoscopic moving image that moves across each pair of imaging planes.
In addition, the three-dimensional display device shown in FIG. 1 only describes the basic configuration. For example, it is clear that aberrations can be reduced by adding an optical system to the three-dimensional display device.
For example, even in the three-dimensional display device shown in FIG. 1, even when the observer 10 is in another position, the above-described effects can be easily obtained by changing or adding an optical system or the like.
[0033]
[Embodiment 2]
The three-dimensional display device according to the second embodiment of the present invention is different from the three-dimensional display device according to the above-described embodiment in that the three-dimensional display device expresses the depth of the three-dimensional object itself.
[Outline of 3D Display Device as Basic of Embodiment of Present Invention]
FIG. 10 is a diagram showing a schematic configuration of a three-dimensional display device which is the basis of Embodiment 2 of the present invention.
Also in the three-dimensional display device shown in FIG. 10, the display light of the two-dimensional image displayed on the two-dimensional display device 100 is imaged in two directions by the polarization type bifocal lens 131 according to the direction of polarized light emitted from the polarization variable device 130. It is separated and displayed on the plane (image plane 203 and image plane 204 in FIG. 10) with a luminance ratio corresponding to the polarization direction.
The basic operation of the 3D display device shown in FIG. 10 will be described below.
First, a 2D image 107 of a three-dimensional object that is a display target object is displayed on the two-dimensional display device 100 to the observer 10.
[0034]
For example, as shown in FIGS. 4 and 5, one polarization variable element of the polarization variable device 130 is made to correspond to one or a plurality of pixels of the display of the two-dimensional display device 100.
Next, the output polarization direction of the corresponding polarization variable element is set to three-dimensional corresponding to one pixel (for example, 140 in FIG. 4) or a plurality of pixels (for example, 141 in FIG. 5) of the two-dimensional display device 100. It changes corresponding to the depth position of the part of the object.
As a result, images having respective luminances corresponding to the outgoing polarization direction are displayed on the imaging plane 203 and the imaging plane 204.
However, the positional relationship of the imaging planes (203, 204) is adjusted in advance using an appropriate optical system so that the images of the imaging plane 203 and the imaging plane 204 overlap on the line of sight of the observer 10.
[0035]
The main point of the three-dimensional display device shown in FIG. 10 is that the luminance of each part of the image on the imaging plane 203 and the imaging plane 204 is changed by changing the outgoing polarization direction in each polarization variable element using the polarization variable device 130. In other words, the overall luminance viewed from the observer 10 is kept constant, and is changed corresponding to the depth position of each part of the three-dimensional object.
An example of how to change this will be described below with reference to FIG.
FIG. 11A is an example of an image formed on an image plane close to the observer, for example, an image plane 203, and FIG. 11B is an image plane far from the observer, such as an image plane. 4 is an example of an image formed on 204.
For example, when a cake as shown in FIG. 11 is taken as an example of a three-dimensional object, the top and bottom surfaces of the cake are, for example, substantially flat, except for the candle that stands on top, and the side surfaces thereof are, for example, For example, the candle is arranged near the circumference of the upper surface.
[0036]
In the 2D image 107 in this case, as shown in FIGS. 11 (a) and 11 (b), the upper side is located at the back on the upper surface and the lower surface, and the middle is at the front and the end on the side surface. As you go, it will be located in the back, and the upper middle part that is hidden will be located in the back.
In this case, the polarization direction of each part changes in consideration of the two intrinsic polarization directions of the polarizing bifocal lens 131 so that the following luminance changes can be obtained on each of the imaging planes (203, 204). You can do it.
First, as shown in FIG. 11A, the luminance change on the upper surface and the lower surface has a portion close to the viewer 10 (for example, the lower side in the 2D image 107) on the imaging surface 203 close to the viewer 10. It changes later corresponding to the depth position so that the brightness | luminance and a far site | part (for example, upper direction in 2D-ized image 107) may become low.
[0037]
Further, in the imaging plane 204 far from the observer 10, as shown in FIG. 11B, a part close to the observer 10 (for example, the lower part in the 2D image 107) has a low luminance and a part far away ( In the 2D image 107, for example, the upper part is gradually changed corresponding to the depth position so that the luminance becomes higher.
Next, the luminance change of the cylindrical portion also corresponds to the depth position, and on the imaging plane 203 close to the observer 10, as shown in FIG. 11A, a part close to the observer 10 (for example, near the middle) ) Is high in luminance and is gradually changed so that a distant portion (for example, near the left and right ends) has low luminance.
Further, in the imaging plane 204 far from the observer 10, as shown in FIG. 11B, a part close to the observer 10 (for example, near the center) has low luminance and a part far away (for example, left and right edges). (Near) is gradually changed so that the brightness increases.
In FIG. 11A and FIG. 11B, the dark portion represents a portion with high luminance.
[0038]
According to the display method described above, even if a two-dimensional image is actually displayed due to a human physiological or psychological factor or illusion, the observer 10 feels as if the upper and lower surfaces are almost flat. It feels like there is a columnar cake.
Thus, according to the three-dimensional display device of the present embodiment, a three-dimensional object having a continuous depth can be expressed easily.
Also in the present embodiment, the multifocal optical device 104 capable of switching a plurality of focal lengths is arranged on the viewer 10 side of the polarizing bifocal lens 131, and the focal length of the multifocal optical device 104 is set. By providing the switching device, the two-dimensional display device 100, and the synchronization device 105 that synchronizes the polarization variable device 130, a continuous depth between any pair of imaging planes among a plurality of pairs of imaging planes. A three-dimensional object having can be expressed easily.
[0039]
[Embodiment 3]
Hereinafter, main examples of the polarizing bifocal lenses (131, 112 to 1 m 2) of the respective embodiments will be described.
FIG. 12 is a diagram showing a schematic configuration of an example of the polarization type bifocal lens of the present embodiment.
The polarization type bifocal lens shown in FIG. 12 includes a fixed focus lens 301 having an optical element shape having no birefringence, and a birefringent region 302.
Here, the fixed focus lens 301 is configured by, for example, an optical system using a combination of glass or plastic convex lens, concave lens, or the like, and the birefringent region 302 is, for example, a birefringent medium such as a liquid crystal. , Calcite, litimi niobate, polymer, or a combination of multiple birefringent crystals containing calcite, litimi niobate, or a stack of polymer thin films uniaxially or biaxially stretched Consists of.
[0040]
Hereinafter, the operation of the polarizing bifocal lens shown in FIG. 12 will be described.
The refractive index of the fixed focus lens 301 is n1, the intrinsic polarization directions in the birefringent region 302 are p21 and p22, and the refractive indexes in the respective polarizations are n21 and n22.
For example, when light is incident from the birefringent region 302, the incident light is separated into polarized light of p21 and p22 according to the polarization state, and after traveling while feeling the refractive index (n21, n22), the light is refracted. This is in contact with the fixed focus lens 301 having the rate n1.
Therefore, the emitted light is imaged at different positions according to the difference in refractive index while being separated into two polarized lights.
That is, it operates as a polarization type bifocal lens that is separated according to the polarization direction.
On the contrary, when the light is incident from the fixed focus lens 301 side, the image is separated and formed on the two image planes by the refractive index corresponding to the intrinsic polarization direction.
[0041]
Here, when liquid crystal is used as the birefringent medium, as shown in FIG. 13, by adding alignment films (303, 304) to both surfaces of the birefringent region 302, the liquid crystal is uniformly aligned. In-plane uniform separation can be obtained for incident light.
Further, by using a liquid crystal having a negative dielectric anisotropy, there is an effect that the orientation is promoted by applying a voltage to stabilize the refractive index anisotropy or maintain transparency.
In addition, when using liquid crystal, the refractive index anisotropy can be stabilized by using a Fresnel structure to reduce the gap, or by reducing the thickness of one lens by combining multiple lenses. And maintaining transparency.
In the polarization type bifocal lens shown in FIGS. 12 and 13, even when there is no fixed focus lens 301, when one or both surfaces of the birefringent region 302 have, for example, a lens shape or a prism shape, Even in the case of 14, it is clear that the same effect as the polarizing bifocal lens shown in FIGS.
[0042]
Next, birefringence can also be obtained by using a birefringent crystal (such as calcite or lithium niobate) or a polymer as the medium of the birefringent region 302.
Here, in terms of production, the liquid crystal is suitable for an increase in size. For example, birefringent crystals such as calcite or lithium niobate have a drawback that it is difficult to increase in size, but compared to the liquid crystal. It has advantages of excellent optical properties such as good transparency and stable refractive index anisotropy.
In the birefringent crystals described above, large crystals are difficult to obtain due to the difficulty of crystal growth.
However, the following method is useful as a method of increasing the size.
In other words, the side surfaces of a plurality of small birefringent crystals are optically polished, and these are optically bonded using an adhesive having the same refractive index.
If the thickness of the bonding surface is sufficiently reduced, a structure that can withstand use can be obtained.
This is optically bonded and then polished into a desired shape, whereby a desired large polarized bifocal lens as shown in FIG. 15 can be obtained.
In FIG. 15, reference numeral 210 denotes a birefringent crystal, and 211 denotes an adhesive portion.
[0043]
Furthermore, it is also possible to form a birefringent medium using a polymer film.
In this case, a polymer having a large refractive index anisotropy is arranged by aligning polymers of a polymer film (for example, a transparent material having a large Δn such as polycarbonate or polystyrene, or PVA, etc.) in a certain direction as much as possible. Need to create.
For this purpose, for example, uniaxial stretching or biaxial stretching is effective.
Alternatively, the polymer can be oriented by repeatedly applying stress to the film.
In the polymer film thus produced, it is difficult to form a thick film.
Therefore, a plurality of thin films prepared in this way are stacked to form a thick film, and this is polished into a desired shape, for example, to obtain a desired large-sized polarization type two as shown in FIG. A focus lens can be obtained.
In FIG. 16, reference numeral 220 denotes an oriented polymer film.
When the polymer film 220 is used, the optical characteristics may be slightly inferior to the case of using the crystal described above, but it has a great advantage in terms of size and weight.
Furthermore, the size can be easily increased as compared with the case where liquid crystal is used.
[0044]
[Embodiment 4]
FIG. 17 is a diagram showing another example of a polarizing bifocal lens that can be used in the three-dimensional display device of each of the embodiments.
The polarization type bifocal lens shown in FIG. 17 includes a polarization beam splitter 401 for separation on the incident side, two types of optical systems (402, 403) having different focal lengths, and a polarization beam splitter 404 for synthesis on the output side. , And plane mirrors (405, 406) for bending the optical path.
Here, the two types of optical systems (402, 403) include, for example, a convex lens, a concave lens, a prism, a convex mirror, a concave mirror, a plane mirror, or a combination thereof.
In the polarization type bifocal lens shown in FIG. 17, the incident light is separated into two intrinsic polarizations (p41, p42) by the polarization beam splitter 401 at a luminance ratio according to the polarization direction, and the respective optical systems (402, 403). ).
For example, since the optical systems (402, 403) have different focal lengths, the polarized light (p41, p42) incident thereon has different imaging distances.
[0045]
Therefore, when both polarizations (p41, p42) are combined by the polarization beam splitter 404, the two intrinsic polarizations (p41, p42) are imaged on different image planes (407, 408).
In this manner, a polarizing bifocal lens that can be separated at a luminance ratio corresponding to the polarization direction can be configured by the optical system shown in FIG.
Here, it is obvious that the same effect can be obtained by using an optical system including the configuration shown in FIG. 18 instead of the polarizing beam splitter 401.
That is, the same effect can be obtained by configuring the beam splitter 410 (for example, a semi-transmission mirror, a semi-transmission prism, etc.) and the polarizing plates (411, 412) whose polarization directions are orthogonal to each other.
Further, it goes without saying that an optical system including the configuration shown in FIG. 18 can be used instead of the polarization beam splitter 404.
[0046]
[Embodiment 5]
Hereinafter, the polarization variable device that can be used in the three-dimensional display device of each of the embodiments will be described.
As a device capable of changing the polarization direction of incident light, such as a polarization variable device used in the three-dimensional display device of each of the embodiments, for example, a medium (for example, liquid crystal) whose birefringence can be changed by an electric field or voltage. And devices using PLZT, etc. are well known.
Many types of devices using liquid crystals are described in, for example, “Liquid Crystal / Fundamentals”, “Liquid Crystal / Applications” (Okano, Kobayashi, Ed.).
Hereinafter, main examples will be described with reference to FIGS.
FIG. 19 is a diagram showing a schematic configuration of a twisted nematic polarization variable device that can be used in the three-dimensional display device of each of the embodiments.
19 includes a transparent conductive film (transparent electrode) 501, an alignment film 502, a nematic liquid crystal region 503, an alignment film 504, and a transparent conductive film (transparent electrode) 505.
In this case, it is common to add a chiral material so that the alignment directions of the alignment film 502 and 504 are orthogonal to each other and the liquid crystal molecules draw a spiral in the same direction.
[0047]
As shown in FIG. 20A, when no voltage is applied between the transparent conductive films (501, 505), the liquid crystal molecules have 90% due to the alignment regulating force of the alignment films (502, 504) and the effect of the chiral material. Rotate to draw a spiral.
For this reason, incident light of linearly polarized light is emitted with the polarization direction changed by approximately 90 degrees due to the optical rotation of the liquid crystal (one of the properties of the birefringent material).
On the other hand, as shown in FIG. 20B, when a sufficient voltage (V5) higher than the threshold voltage is applied between the transparent conductive films (501, 505), the liquid crystal molecules are aligned in the applied voltage direction.
For this reason, the polarization direction of incident light is emitted with almost no change.
When the voltage applied between the transparent conductive films (501, 505) is V5 or less, a change in the polarization direction according to the voltage is continuously obtained.
Thus, the polarization direction of incident light can be varied by the voltage applied between the transparent conductive films (501, 505).
Furthermore, it is generally well known that these elements are arranged in a matrix and driven using an active drive element or the like.
[0048]
FIG. 21 is a diagram showing a schematic configuration of an in-plane type polarization variable device that can be used in the three-dimensional display device of each of the embodiments.
The in-plane polarization variable device shown in FIG. 21 includes a transparent conductive film (transparent electrode) 601, an alignment film 602, a nematic liquid crystal region 603, an alignment film 604, and a transparent conductive film (transparent electrode) 605.
Here, the alignment directions of the alignment film 602 and 604 are parallel, and the transparent conductive films (601, 605) are in the same plane.
As shown in FIG. 22A, when no voltage is applied between the transparent conductive films (601, 605), the liquid crystal molecules are aligned in the alignment direction by the alignment regulating force of the alignment films (602, 604).
On the other hand, as shown in FIG. 22B, when a sufficient voltage (V6) higher than the threshold voltage is applied between the transparent conductive films (601, 605), the liquid crystal molecules are aligned in the applied voltage direction.
As described above, since the alignment direction of the liquid crystal having birefringence changes, the polarization state of the emitted light can be changed.
Furthermore, when the voltage applied between the transparent conductive films (601, 605) is V6 or less, the change in the polarization direction according to the voltage is continuously obtained.
It is generally well known that these elements are arranged in a matrix and driven using an active drive element or the like.
[0049]
FIG. 23 is a diagram showing a schematic configuration of a homogeneous polarization variable device that can be used in the three-dimensional display device of each of the embodiments.
23 includes a transparent conductive film (transparent electrode) 611, an alignment film 612, a liquid crystal (for example, nematic liquid crystal) region 613, an alignment film 614, and a transparent conductive film (transparent electrode) 615. .
In the homogeneous type polarization variable device shown in FIG. 23, since the liquid crystal of homogeneous alignment is used, the alignment directions of the alignment film 612 and the alignment film 614 are the same (parallel).
Further, in the homogeneous polarization variable device shown in FIG. 23, incident light whose polarization direction is shifted from the alignment direction of the alignment film is incident.
For example, as shown in FIG. 24A, when the incident light is linearly polarized light, the incident light whose polarization direction is shifted to an intermediate direction (for example, 45 degrees) between the 0 degree direction and the 90 degree direction is changed to FIG. Is incident on the homogeneous polarization variable device shown in FIG.
Further, as shown in FIGS. 24B and 24C, circularly polarized light or elliptically polarized light is incident on the homogeneous polarization variable device shown in FIG.
[0050]
As shown in FIG. 25B, when a sufficient voltage (V7) higher than the threshold voltage is applied between the transparent conductive films (611, 615), the liquid crystal molecules are aligned in the applied voltage direction.
For this reason, incident light is emitted with almost no change in polarization direction.
On the other hand, as shown in FIG. 25A, when no voltage is applied between the transparent conductive films (611, 615), the liquid crystal molecules are aligned due to the alignment regulating force of the alignment films (612, 614). It is aligned in the direction and parallel to the alignment film (612, 614).
Therefore, incident light is emitted with the polarization direction changed by the birefringence of the liquid crystal.
Furthermore, when the voltage applied between the transparent conductive films (611, 615) is V7 or less, the change in the polarization direction according to the voltage is continuously obtained.
Thus, the polarization direction of incident light can be varied by the applied voltage applied between the transparent conductive films (611, 615).
It is also well known that these elements are arranged in a matrix and driven using an active drive element or the like.
In addition to nematic liquid crystals, it is clear that there are various devices that can obtain the same effect using ferroelectric liquid crystals, polymer dispersed liquid crystals, polymer liquid crystals, and the like.
[0051]
[Embodiment 6]
Hereinafter, main examples of the polarization switching units (111 to 1m1) that can be used in the three-dimensional display device according to each of the embodiments will be described.
In the following, the case where liquid crystal is mainly used will be described. However, the use of liquid crystal has an advantage that the size can be easily increased as compared with the case where an electro-optic crystal is used.
FIG. 26 is a diagram illustrating a schematic configuration of an example of a polarization switch (111 to 1m1) that can be used in the three-dimensional display device according to each of the embodiments.
The polarization switch shown in FIG. 26 is a ferroelectric polarization switch, and as shown in the figure, a transparent conductive film 621, an alignment film 622, a liquid crystal region (for example, a ferroelectric liquid crystal or a polymer ferroelectric liquid crystal). Etc.) 623, an alignment film 624, and a transparent conductive film 625.
Since the polarization switch shown in FIG. 26 uses ferroelectric liquid crystal, the alignment direction of the alignment film 622 and the alignment direction of the alignment film 624 are made parallel.
In the ferroelectric liquid crystal, the direction of the dipole of the ferroelectric liquid crystal molecule changes depending on the direction of the applied voltage, thereby changing the direction of the ferroelectric liquid crystal molecule.
For this reason, the polarization direction of incident light can be varied by the voltage applied between the transparent electrodes (621, 625).
[0052]
Ferroelectric liquid crystals or polymer ferroelectric liquid crystals have the advantage of speeding up because the direction of the dipole is forcibly changed by voltage as described above.
Further, the use of a polymer ferroelectric liquid crystal has an advantage that the size can be increased while maintaining high speed.
In addition, as a liquid crystal capable of high-speed binary switching, a bistable nematic liquid crystal can be used although its response speed is slightly inferior to that of a ferroelectric liquid crystal.
Although the invention made by the present inventor has been specifically described based on the above-described embodiment, the present invention is not limited to the above-described embodiment, and various modifications can be made without departing from the scope of the invention. Of course.
[0053]
【The invention's effect】
The effects obtained by the representative ones of the inventions disclosed in the present application will be briefly described as follows.
ADVANTAGE OF THE INVENTION According to this invention, the contradiction between the physiological factors of a stereoscopic vision can be suppressed, information content can be reduced, and it becomes possible to reproduce | regenerate the electrically rewritable three-dimensional moving image.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating a schematic configuration of a three-dimensional display device according to a first embodiment of the present invention.
FIG. 2 is a diagram showing a schematic configuration of a three-dimensional display device serving as a basis of Embodiment 1 of the present invention.
3 is a diagram for explaining a 2D image generation method in the three-dimensional display device shown in FIG. 2; FIG.
4 is a diagram for explaining a correspondence relationship between each pixel of the two-dimensional display device and each polarization variable element of the polarization variable device in the three-dimensional display device shown in FIG. 2; FIG.
5 is a diagram for explaining a correspondence relationship between each pixel of the two-dimensional display device and each polarization variable element of the polarization variable device in the three-dimensional display device shown in FIG. 2;
6 is a diagram for explaining a method of displaying a three-dimensional image in the three-dimensional display device shown in FIG.
7 is a diagram for explaining a method of displaying a three-dimensional image in the three-dimensional display device shown in FIG.
8 is a diagram for explaining a method of displaying a three-dimensional image in the three-dimensional display device shown in FIG.
9 is a diagram for explaining a method of displaying a three-dimensional image in the three-dimensional display device shown in FIG.
FIG. 10 is a diagram showing a schematic configuration of a three-dimensional display device which is the basis of Embodiment 2 of the present invention.
11 is a diagram for explaining a method of displaying a three-dimensional image in the three-dimensional display device shown in FIG.
FIG. 12 is a diagram showing an example of a polarized bifocal lens that can be used in the three-dimensional display device according to each embodiment of the present invention.
13 is a diagram for explaining the relationship between incident light and outgoing light in the polarization type bifocal lens shown in FIG. 12; FIG.
FIG. 14 is a diagram showing another example of a polarizing bifocal lens that can be used in the three-dimensional display device according to each embodiment of the present invention.
FIG. 15 is a diagram showing a schematic configuration of another example of a polarizing bifocal lens according to an embodiment of the present invention.
FIG. 16 is a diagram showing a schematic configuration of another example of a polarizing bifocal lens according to an embodiment of the present invention.
FIG. 17 is a diagram showing another example of a polarizing bifocal lens that can be used in the three-dimensional display device according to each embodiment of the present invention.
18 is a diagram showing an optical system that can be used in place of the polarization beam splitter shown in FIG. 17;
FIG. 19 is a diagram showing a schematic configuration of a twisted nematic polarization variable device that can be used in the three-dimensional display device according to each embodiment of the present invention.
20 is a diagram for explaining the operating principle of the twisted nematic polarization variable device shown in FIG. 19;
FIG. 21 is a diagram showing a schematic configuration of an in-plane polarization variable device that can be used in the three-dimensional display device according to each embodiment of the present invention.
22 is a diagram for explaining the operation principle of the in-plane type polarization variable device shown in FIG. 21. FIG.
FIG. 23 is a diagram showing a schematic configuration of a homogeneous polarization variable device that can be used in the three-dimensional display device of each embodiment of the present invention.
24 is a diagram showing incident light incident on the homogeneous polarization variable device shown in FIG. 23 and the alignment direction of the alignment film.
25 is a diagram for explaining the operating principle of the homogeneous polarization variable apparatus shown in FIG.
FIG. 26 is a diagram showing a schematic configuration of an example of a polarization switching device that can be used in the three-dimensional display device of each embodiment of the present invention.
FIG. 27 is a diagram showing a schematic configuration of an example of a conventional three-dimensional display device.
FIG. 28 is a diagram showing a schematic configuration of another example of a conventional three-dimensional display device.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 10 ... Observer, 100,705 ... Two-dimensional display apparatus, 104 ... Multifocal optical apparatus, 105 ... Synchronizer, 106 ... Three-dimensional object (display object), 107 ... 2D-ized image, 111-1m1 ... Polarization switch , 112-1m2, 131 ... polarization type bifocal lens, 130 ... polarization variable device, 140, 141 ... pixel, 150, 151 ... polarization variable element, 203-2m3, 204-2m4, 407, 408 ... imaging plane, 210 ... birefringent crystal, 211 ... connecting portion, 220 ... polymer film, 301 ... fixed focus lens, 302 ... birefringent region, 303, 304, 502, 504, 602, 604, 612, 614, 622, 624 ... Alignment film, 401, 404 ... polarization beam splitter, 402, 403 ... optical system, 405, 406 ... plane mirror, 410 ... beam splitter, 411, 412 ... polarization 501, 505, 601, 605, 611, 615, 621, 625 ... transparent conductive film, 503, 603, 613, 623 ... liquid crystal region, 702, 703 ... camera, 704 ... video signal converter, 706 ... liquid crystal shutter glasses 712: Collection of two-dimensional images, 713: Volumetric three-dimensional display device, 714: Three-dimensional redevelopment.

Claims (17)

For a plurality of display surfaces arranged at different depth positions as viewed from the viewer, a two-dimensional image is generated by projecting the display target object from the viewer's line of sight,
The generated two-dimensional image is displayed on any two display surfaces of the plurality of display surfaces, and the luminance of the displayed two-dimensional image is set to any two of the plurality of display surfaces. A three-dimensional display method for generating a three-dimensional stereoscopic image by changing each display surface independently.
Polarization direction of incident light disposed between (n + 1) polarization type bifocal lenses having different focal lengths with respect to two independent polarization directions and the (n + 1) polarization type bifocal lenses. Is converted into one of the two independent polarization directions by a polarization-type multifocal optical system, and the two-dimensional image display light is converted into the two independent polarization directions. And splitting the display light for each of the two independent polarization directions into images on any two display surfaces of the plurality of display surfaces,
The polarization direction of the n polarization switchers is switched in synchronization with a two-dimensional image formed on any two display surfaces of the plurality of display surfaces, and the polarization direction of the display light is controlled. And the brightness | luminance of the said two-dimensional image imaged on two arbitrary display surfaces in the said several display surface is changed independently, The three-dimensional display method characterized by the above-mentioned. When the depth position of the display target object is close to the observer, the brightness of the two-dimensional image formed on the display face close to the observer is high among the two display faces. Controlling the polarization direction of the display light so that the luminance of the two-dimensional image formed on the display surface far from the observer among the display surfaces is low,
When the depth position of the display target object is a position far from the observer, the brightness of the two-dimensional image formed on the display surface close to the observer among the two display surfaces is low. 2. The tertiary according to claim 1, wherein a polarization direction of the display light is controlled so that a luminance of a two-dimensional image formed on a display surface far from the observer among the display surfaces is increased. Original display method. The two-dimensional image is sequentially switched within the afterimage time of the human eye, and the display light of each two-dimensional image is sequentially imaged on any two display surfaces of the plurality of display surfaces, The three-dimensional display method according to claim 1, wherein a three-dimensional moving image is generated. The three-dimensional display method according to claim 3, wherein the polarization direction of the display light is sequentially switched for each of the two-dimensional images. When the depth position of each part of the two-dimensional image is a position close to the observer, each part of the two-dimensional image formed on the display surface close to the observer among the two display surfaces high luminance, the two display surfaces the observer far display surface is the two-dimensional image the lower the brightness of each part of the imaging within the, and the depth position of each part of the two-dimensional image When the position is far from the observer, the luminance of each part of the two-dimensional image formed on the display surface close to the observer among the two display surfaces is low, and the two display surfaces The polarization direction of the display light is controlled for each part of the two-dimensional image so that the luminance of each part of the two-dimensional image formed on the display surface far from the observer is high. The three-dimensional display method according to claim 1. Two-dimensional image display means for displaying a two-dimensional image;
Polarization variable means for controlling the polarization direction of the display light of the two-dimensional image incident from the two-dimensional image display means and emitting it,
A plurality of display lights emitted from the polarization varying means are separated into two independent polarization directions, and the display lights for the two independent polarization directions are arranged at different depth positions as viewed from the observer. A polarization-type multifocal optical system that forms an image on any two of the display surfaces;
A synchronization device,
The two-dimensional images formed on any two display surfaces of the plurality of display surfaces are overlapped on the observer's line of sight and become two-dimensional images having different depth positions. A three-dimensional display device in which a three-dimensional image display means, the polarization variable means, and the polarization type multifocal optical system are arranged,
The polarizing multifocal optical system includes (n + 1) polarizing bifocal lenses having different focal lengths with respect to the two independent polarization directions,
N polarization switching units disposed between the (n + 1) polarization type bifocal lenses and converting the polarization direction of incident light into one of the two independent polarization directions; Have
The synchronization device switches a polarization direction of the n polarization switching units in synchronization with a two-dimensional image formed on any two display surfaces of the plurality of display surfaces, and also varies the polarization. The two-dimensional image formed on any two display surfaces of the plurality of display surfaces by controlling the polarization direction of the display light of the two-dimensional image emitted from the two-dimensional image display unit A three-dimensional display device characterized by independently changing the brightness of the display. When the depth position of the object to be displayed is a position close to the observer, the polarization varying unit is configured to generate a two-dimensional image formed on a display surface close to the observer among the two display surfaces. Display of the two-dimensional image incident from the two-dimensional image display means so that the luminance of the two-dimensional image formed on the display surface far from the observer is low among the two display surfaces. Control the polarization direction of light,
When the depth position of the display target object is a position far from the observer, the brightness of the two-dimensional image formed on the display surface close to the observer among the two display surfaces is low. The polarization direction of the display light of the two-dimensional image incident from the two-dimensional image display means is controlled so that the luminance of the two-dimensional image formed on the display surface far from the observer among the display surfaces becomes high. The three-dimensional display device according to claim 6. The three-dimensional display device according to claim 6 or 7, wherein the polarization changing unit changes the display light of the two-dimensional image incident from the two-dimensional image display unit to elliptically polarized light. The polarization variable means changes the display light of the two-dimensional image incident from the two-dimensional image display means to the two independent polarization directions or linearly polarized light having an angle intermediate between the two independent polarization directions. The three-dimensional display device according to claim 6 or 7, wherein The three-dimensional display device according to claim 6, wherein the polarization varying unit includes a liquid crystal. The two-dimensional image display means has a plurality of pixels,
Further, the polarization variable means has a plurality of polarization variable elements,
11. Each polarization variable element of the polarization variable means controls the polarization of display light of one or a plurality of pixels of the two-dimensional image display means, respectively. The three-dimensional display device described in 1. The polarization type bifocal lens includes a fixed focus lens region having a fixed refractive index and a birefringent medium having birefringence. 3D display device. The three-dimensional display device according to any one of claims 6 to 11, wherein the polarizing bifocal lens includes a birefringent medium having a lens shape or a prism shape on one side or both sides. . The birefringent medium may be a liquid crystal, calcite, lithium niobate, polymer, a plurality of calcite or lithium niobate optically bonded, or a plurality of polymer thin films uniaxially or biaxially stretched. The three-dimensional display device according to claim 12 or 13, characterized by comprising: The polarizing bifocal lens includes first and second optical systems having different optical characteristic values;
A first polarization beam splitter that impinges light in one of the two independent polarization directions incident on the first optical system and the other incident on the second optical system;
12. The three-dimensional device according to claim 6, further comprising a second polarization beam splitter that synthesizes light that has passed through the first optical system and the second optical system. Display device. The polarizing bifocal lens includes first and second optical systems having different optical characteristic values;
A first beam splitter that separates incident light into two lights;
A first polarizing plate on which one light separated by the first beam splitter is incident and light in one polarization direction of the two independent polarization directions is incident on the first optical system;
A second polarizing plate on which the other light separated by the first beam splitter is incident, and light in the other polarization direction of the two independent polarization directions is incident on the second optical system;
12. The three-dimensional display according to claim 6, further comprising: a second beam splitter configured to synthesize the light that has passed through the first optical system and the second optical system. apparatus. The three-dimensional display device according to claim 1, wherein the polarization switch includes a liquid crystal.

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