JP4495982B2 - Stereoscopic image display device and light deflection element - Google Patents

Description

  The present invention relates to an image display device that uses a light deflection unit that changes the direction of light by an electric signal in an image display device that enables recognition of a three-dimensional image without requiring special glasses. More specifically, the present invention relates to an image display device in which a plurality of positions where stereoscopic images can be observed are set.

As a technique for displaying a stereoscopic image, various stereoscopic display devices have been studied. A conventional stereoscopic display device has been proposed in which an observer wears special glasses (for example, glasses whose polarization directions are different by 90 ° between the left eye lens and the right eye lens) (for example, patents). Reference 1).
In a stereoscopic display device that does not use special glasses, binocular parallax is obtained using a stripe light source (for example, see Patent Document 2), a parallax barrier, a lenticular lens (for example, see Patent Documents 3 and 4), and the like. A projection-type stereoscopic display device or a direct-view type stereoscopic display device that realizes stereoscopic viewing by separately presenting images having left and right eyes has been proposed.

  In the above-described prior art, the principle of displaying a stereoscopic image is that the display screen is separated into right and left images by a striped barrier (striped light source), a cylindrical lens (lenticular lens), etc. The visual image and the left-eye image are visually recognized and parallax is used to allow the observer to recognize the stereoscopic image. In Patent Document 2, the display image is separated into left and right images by a striped light source. However, since the display image is displayed by a light source including a light-shielding portion of the stripe, the horizontal resolution viewed by the observer is reduced. To do. Further, in Patent Document 3, the aperture ratio overlaps with an existing image display device (light valve) to improve the resolution. However, since a plurality of image display devices are used, the size of the device increases and the cost increases. Further, in Patent Document 4, a stereoscopic image is displayed by spatially separating the left and right images by means of polarization direction switching means synchronized with the left and right images displayed in a time division manner and a lenticular lens with a polarizing plate array. . Although the resolution of the left and right images is the same as that of the existing liquid crystal panel, the size of one pixel in the left and right images becomes ½ due to the polarization direction switching means and the polarizing plate array, and the light use efficiency is lowered.

In the image display device that displays a stereoscopic image without using special glasses as described above, the left and right images are displayed in stripes on the display element, so that there is a problem in that the horizontal resolution decreases. In order to improve the resolution, there are problems such as an increase in the size of the apparatus and a decrease in light utilization efficiency.
In order to remedy these problems, the present applicant, in Japanese Patent Application No. 2003-115766, as an image display device that displays a stereoscopic image without using special glasses, displays an image displayed on the image display means by one pixel in the left-right direction. A three-dimensional image display method and apparatus have been proposed in which the light is shifted by vibration and the light passing through the left and right image separating means is visually recognized by the light deflecting means in the left-right direction in synchronism with the vibrational shift of the image.
However, in the prior application, the position where the image can be observed is only one place within a limited range, and a good stereoscopic image cannot be observed at a plurality of places.

JP-A-53-80114 JP-A-7-181429 JP-A-5-232435 Japanese Patent No. 2908300

In a conventional stereoscopic image display apparatus that does not use glasses, a method of performing space division corresponding to a plurality of observation positions on an image display means to display the problem in order to improve the problem that the observation position range that can be recognized as a stereoscopic image is narrow However, since the substantial resolution decreases as the number of space divisions is increased, it has not been possible to view a high-definition image by a plurality of people.
An object of the present invention is to provide a stereoscopic image display method capable of viewing a high-definition image by a plurality of persons.

According to the first aspect of the present invention, image display means arranged at a predetermined distance from a plurality of viewpoints, image separation means arranged on the viewpoint side with respect to the image display means, and transmission through the image separation means Light deflecting means for deflecting the image light corresponding to the plurality of viewpoints, and the image display means has a plurality of input images formed corresponding to the plurality of viewpoints, each of m and L being 2 It is characterized by a stereoscopic image display device that is divided and displayed spatially and temporally so that the number of space divisions is L and the number of time divisions is m .
According to a second aspect of the present invention, in the stereoscopic image display device according to the first aspect, when the width of each divided area on the image display means is d, the image separation means has a pitch Ds = L × d. The structure is characterized in that the shape, refractive index, or transmittance changes periodically .

According to a third aspect of the present invention, in the stereoscopic image display device according to the first or second aspect, the number of positions deflected by the light deflecting means is m .
According to a fourth aspect of the present invention, in the stereoscopic image display device according to any one of the first to third aspects, when n input images are formed corresponding to the plurality of viewpoints, n = It is characterized by the relationship of L × m .
According to a fifth aspect of the present invention, in the stereoscopic image display device according to any one of the first to fourth aspects, the timing at which the deflection direction is switched by the light deflection means is synchronized with the image rewriting timing of the image display means. It is characterized by being allowed .
According to a sixth aspect of the present invention, in the stereoscopic image display device according to any one of the first to fifth aspects, the main scanning direction of the image display means is a vertical direction .

According to a seventh aspect of the present invention, in the stereoscopic image display device according to any one of the first to fifth aspects, the image rewriting timing of the image display means is collectively performed for all pixels. To do.
According to an eighth aspect of the present invention, in the stereoscopic image display device according to any one of the first to seventh aspects, at least one inner surface side of the light deflection means is inclined corresponding to the light deflection direction. It comprises an optical deflection element comprising a pair of substrates having a region, a liquid crystal layer composed of a smectic C phase or a nematic phase sandwiched between both substrates, and an electrode for applying a voltage to the liquid crystal layer. .
According to a ninth aspect of the present invention, in the stereoscopic image display device according to the eighth aspect, the inclined region is a saw-tooth shaped substrate formed in a saw-tooth shape .

According to a tenth aspect of the present invention, in the stereoscopic image display device according to any one of the first to ninth aspects, there are a plurality of the light deflection elements, and a deflection angle of each of the light deflection elements is a maximum deflection angle. When the deflection angle is θ0 with respect to a large optical deflection element and the number of additional optical deflection elements is k (k ≧ 1), assuming that the deflection angle of the jth optical deflection element is θj, θj = θ0 X (1/2) ^j (j = 1,... K)
According to an eleventh aspect of the present invention, in the stereoscopic image display device according to any one of the first to tenth aspects, the image display means is a direct view type liquid crystal display device .
According to a twelfth aspect of the present invention, in the stereoscopic image display device according to any one of the first to tenth aspects, the image display means is a projection type liquid crystal display device made of LCOS .

According to a thirteenth aspect of the present invention, in the stereoscopic image display device according to any one of the first to tenth aspects, the image display means is a projection type liquid crystal display device, and the pixels to be projected into the light valve It has an opening control part for restricting the magnitude | size of below to a pixel pitch or less .
According to a fourteenth aspect of the present invention, in the stereoscopic image display device according to the thirteenth aspect, the aperture control unit is a microlens provided for each pixel .
According to a fifteenth aspect of the present invention, in the stereoscopic image display device according to any one of the first to fourteenth aspects, the image separating means is a lenticular lens .
According to a sixteenth aspect of the present invention, in the stereoscopic image display device according to the eighth aspect, the light deflection element has sawtooth-shaped cross sections on both inner surfaces of the pair of substrates, and inclined surfaces thereof are symmetrical with respect to the liquid crystal layer. The refractive index of one substrate is set equal to the ordinary refractive index of the liquid crystal layer, and the refractive index of the other substrate is set to be equal to the extraordinary light refractive index .

  The present invention is a display method that does not deteriorate the resolution even when the number of input image divisions for viewing by a plurality of persons is increased as compared with the conventional spatial division method, and the conventional display device technology has a simple configuration. Can provide a stereoscopic image resolution that is impossible.

FIG. 1 is a diagram for explaining the principle of stereoscopic vision. FIG. 4A is a diagram for explaining the positional relationship between a plurality of objects and both eyes, and FIG. 4B is a diagram for explaining the incident angle of light with respect to both eyes and the positional relationship on the retina.
In the figure, symbol a represents a human eye width, P and Q represent objects, D represents an object distance, S represents a display surface, and Z represents an observer.
The display principle of the stereoscopic display system will be described with reference to the drawings.
When the observer Z looks at the object P in front of the right eye of the observer Z as shown in FIG. 10A, the right eye is viewed based on the separation distance a between the left and right eyes as shown in FIG. On the retina, the object P is captured at the same PR ′ position as FR which is the center position of the retina, and on the retina of the left eye, the position of PL ′ slightly shifted from the FL which is the center position of the retina. To be captured. In other words, the right eye appears to be located straight ahead, but the left eye appears to be located closer to the right eye. When the observer Z views the object Q in front of the left eye as shown in FIG. 10A, the left eye is placed on the retina of the left eye based on the distance a between the left and right eyes as shown in FIG. The object Q is captured at the position QL ′, and the object Q is captured at the position QR ′ on the retina of the right eye. That is, the left eye appears to be located straight ahead, but the right eye appears to be located closer to the left eye. That is, a shift occurs in the position of the object image formed on the retinas of the left and right eyes. This amount of deviation is called binocular parallax.

  By using the binocular parallax to provide valuable information on the depth of the object on the display surface S, it is possible to capture the object in a three-dimensional manner. Therefore, in order to reproduce the objects P and Q on the display surface at the observation distance D0, on the display surface, the image for the left eye of P is at the position PL "and the image for the right eye of P is PR". The image for the left eye of Q is formed in QL ″, the image for the right eye of Q is formed in QR ″, and the image formed in the position of PR ″ and QR ″ with the right eye is formed with the left eye. The image formed at the position of PL ″ and QL ″ may be recognized.

FIG. 2 is a diagram illustrating an example of a method for viewing different images between the left and right eyes.
FIG. 3 is a diagram illustrating another example of a method for viewing different images with the left and right eyes.
In both figures, (a) is a schematic diagram showing the positional relationship between the image display means and the observer, and (b) is a diagram showing pixels in which the left and right eyes can be observed. In either case, the pixel portion is exaggerated.
In the figure, reference numeral DISP indicates display means, SB indicates a slit-like barrier, and LL indicates a lenticular lens.
As shown in FIG. 2, there is a configuration in which a slit-like barrier SB having a light shielding portion and an opening is provided between the image display means DISP for generating and displaying the left and right images and the observer Z. The image display means DISP alternately displays the left and right images to be displayed in a strip shape. The observer Z observes from a position away from the display surface S by a specific distance D0. Since the barrier SB installed in front of the display surface S is installed so that the left and right images can be visually recognized by the left and right eyes, the observer Z recognizes as a stereoscopic image by binocular parallax. Here, the right image is rn, the left image is ln, n = 1, 2, 3,. In FIG. 4B, the pixels r1 and l1 are shown at the same position because the left and right eyes visually recognize that r1 and l1 are at the same position. In this way, the position where the entire image can be seen (the positions of the left and right eyes in the figure) will be referred to as the viewpoint here. In this example, two viewpoints are shown.
In the case of the method using the slit barrier SB, the resolution is basically determined by the pitch of the openings. However, since the area blocked by the light shielding part as the barrier is an area where nothing can be seen as an image, The images viewed by each of them are intermittent, and the horizontal resolution feels lower than actual.
Further, as shown in FIG. 3A, there is a configuration in which the left and right images are visually recognized by the left and right eyes using a lenticular lens LL in which cylindrical lenses are arranged in a strip shape instead of the slit barrier SB. In these configurations, in order to perform stereoscopic display, the left and right images displayed by the image display means must be alternately displayed in a strip shape. In the case of this method, the image is enlarged in the left-right direction by the lenticular lens LL, so that it can appear to be continuous with the image from the adjacent lens. Therefore, the resolution is determined by the pitch of the lenticular lens LL.

FIG. 4 is a diagram illustrating an example of an image display device that increases resolution by deflecting light in a time-sharing manner. FIG. 4A is a diagram showing a display state at a certain point in time division, and FIG. 4B is a diagram showing a display state at the next subsequent point.
FIG. 5 is a diagram for explaining pixels visually recognized by the left and right eyes by repeating the display of FIG.
In FIG. 4, symbol LC indicates a light deflecting means.
In the slit barrier system, the resolution reduction can be improved by deflecting light. In FIG. 4A, the light deflection means LC is installed at the position shown in the figure, and an image O as shown in the figure is displayed on the display means DISP in a state where the light deflection means LC is not operated.
Next, by changing the direction of the image light as shown in FIG. 4B by applying the light deflecting means LC, the pixels that are visually recognized by the left and right eyes change. At this time, when the light deflection means LC is switched, an image O ′ (this image is temporarily called a hidden image) that is not visible on the barrier SB is displayed so that the image to be visually recognized is not reversed left and right. Swap the position of the image to be inserted. However, when creating a hidden image, the content of the image is shifted by one pixel in the left direction in FIG. In this way, when looking at the image O, the image O ′ that was not visible at the light-shielding portion appears as if it is at the position of the light-shielding portion.
That is, by switching the light deflection at high speed, switching the image O and the hidden image O ′ at the time of switching, and switching the display positions of the left and right display images to display the images that the left and right eyes respectively recognize. As shown in FIG. 5, a continuous high-definition image is visually recognized, and the stereoscopic display image recognized is also high-definition.
In this method, when the first image O is shifted to the left by one pixel without using the hidden image O ′, the resolution of the image does not increase, and the image as shown in FIG. Is recognized.

FIG. 6 shows an example of a stereoscopic display device in which three places are set as a plurality of observation positions.
In the figure, symbol L indicates a pixel, and Ob indicates a viewpoint.
Next, a method for displaying a stereoscopic image in which a plurality of input images formed corresponding to a plurality of viewpoints are observed at a plurality of observation positions will be described.
View the four viewpoints in Ob. 1 to 4, and the interval between the positions is set substantially equal to a in FIG. When one convex part (lens part) with a lenticular lens is observed from each viewpoint, images (L1 to L4) of the image display means corresponding to each viewpoint are observed. For example, Ob. The L1 image is observed from one position. Images L1 to L4 are formed corresponding to each viewpoint. For example, Ob. The right eye is at position Ob. If the left eye is positioned at position 2, the stereoscopic image formed by L1 and L2 is observed. Similarly, Ob. 2 and Ob. 3, Ob3. And Ob. 4, the stereoscopic images formed by L2 and L3, and L3 and L4 are recognized, and stereoscopic image observation from three observation positions can be performed. Images seen from the respective observation positions are the same as in the state shown in FIG.

FIG. 7 is a conceptual diagram for explaining a method of creating the stereoscopic image shown in FIG.
In the figure, reference numeral C denotes a camera.
As the input image, for example, as shown in FIG. 7, four cameras (C1 to C4) are arranged at a predetermined interval, and images taken by each camera can be processed and used. The position of this camera corresponds to the viewpoint at the observation stage. In the figure, images of Image1 to Image4 are formed by four cameras that photograph the subject, respectively, but these images have a division width d determined by the pitch of the lenticular lens and the number of spatial divisions (in this case, 4). After the division, the images are arranged in order and become the input image of the image display means in FIG.
As the number of observation positions increases, more observers can use it at the same time, increasing convenience, and when the viewpoint is moved, the observation angle of the subject changes accordingly, so that it can be recognized as a more natural and stereoscopic image. become. Conversely, however, the more the observation positions, the lower the actual resolution. In the figure, ¼ of the resolution of the image display means is the resolution perceived by each observer. Therefore, a stereoscopic image display method and a stereoscopic image display apparatus that can set a larger number of observation positions and do not cause a reduction in resolution are important.

FIG. 8 is a schematic view of the stereoscopic image display apparatus of the present invention.
FIG. 9 is a conceptual diagram for explaining a method of creating the stereoscopic image shown in FIG.
FIG. 10 is a timing chart for displaying an image on the display device shown in FIG.
The stereoscopic image display apparatus of the present invention has a configuration in which light deflecting means is added to the front surface of the display apparatus shown in FIG. In this configuration, a plurality of input images formed corresponding to a plurality of viewpoints are displayed in an image display unit that is divided and displayed spatially and temporally, and an image arranged on the front side (observer side) of the image display unit Separating means and light deflecting means for deflecting the image light transmitted through the image separating means corresponding to a plurality of observation positions.
The space division number here is a number for dividing a display unit of the image display means, that is, a range corresponding to one lens portion in FIG. 6, and is 4 in FIG. The number of time divisions is the number of images when a predetermined time is divided and a plurality of images are displayed. FIG. 8 shows an example in which the space division number L is 2 and the time division number m is 2. There are four input images.

First, in a state where the light deflecting means does not function, the outgoing light path from the image display means is as shown by the broken line in FIG. L and Ob. It is assumed that the position is R. By causing the optical deflecting means to function, incident light is emitted after being rotated (deflected) clockwise or counterclockwise in accordance with a control signal for the optical deflecting means. Now, the light deflection means is made to function and Ob. The optical path toward R is Ob. 1, Ob. The optical path toward L is Ob. 3, it is assumed that the angle is deflected by −θ counterclockwise. Corresponding to this deflection, control is performed so that images at predetermined positions of the image display means are displayed as images L1 and L3, respectively. As shown in FIG. 9, an input image is prepared by dividing L1 and L3 spatially and merging in advance. After this state is maintained for a predetermined time t1 as shown in FIG. 10, the light deflection means is caused to function in the reverse direction (clockwise direction). The optical path toward R is Ob. 2, Ob. The optical path toward L is Ob. 4 is deflected by + θ. Corresponding to this deflection, control is performed so that images at predetermined positions of the image display means are displayed as images L2 and L4, respectively. As described above, an input image is prepared by spatially dividing L2 and L4 and merging them. After holding this state for a predetermined time t2, the operation performed at t1 is repeated. That is, the L1 / L3 input image and the L2 / L4 input image are displayed in a time division manner.
With the above operation, a stereoscopic image display apparatus having a double viewpoint with the same resolution can be realized with a simple configuration in which the light deflecting means is added to the conventional configuration shown in FIG. It is preferable that t1 and t2 be short intervals so that the observer does not feel flicker. For example, t1 = t2 = 16.7 ms (equivalent to 30 Hz display) may be set.

Here, as the image separation means, when the number of spatial divisions of the input image is L and each division width on the image display means is d, the shape, refractive index or transmittance changes periodically at a pitch Ds = L × d. Therefore, a good stereoscopic image with little leakage light can be obtained. In the present invention, when the input image is divided / merged, it is preferable to dispose the input image in consideration of the deflection of the optical path in the optical deflection element. For example, in FIG. 1 is an image of a divided region described as L1 of the image display means. At position 1, it is recognized that an image is present at position L ′ on the right side of this region. Accordingly, it is preferable to display an image corresponding to the position of L ′ as the image signal of L1.
The condensing point, that is, the observation distance may be appropriately set depending on the size of the screen of the image display device and the assumed number of observers, but is preferably about 0.5 to 5 m. As the periodic structure, the lenticular lens type is particularly excellent because of good controllability during formation and light utilization efficiency.

FIG. 11 is a diagram showing an example in which the light deflecting means is used in two stages.
In the description using FIG. 8, the number of light deflecting positions is 2 (Ob.R is assigned to Ob.1 and Ob.2, or Ob.L is assigned to Ob.3 and Ob.4). Many more positions can be provided. That is, as shown in FIG. 11, the viewpoints can be doubled to four while keeping the interval substantially by stacking the light deflection means one more stage and setting the light deflection angle ± θ / 2. In this case, the observation position of the stereoscopic image corresponds to (Ob.1 / Ob.2), (Ob.2 / Ob.3)... (Ob.7 / Ob.8) corresponding to L1 to L8. A total of 7 positions can be obtained by combining the two. Although not shown in the figure, the number of viewpoints can be further doubled while keeping the interval substantially by overlapping the light deflecting means and setting the light deflection angle to ± θ / 4. That is, when the deflection angle of each optical deflection element is k with respect to the deflection angle θ0 of the optical deflection element having the largest deflection angle, the deflection angle θj of the j-th optical deflection element. Is (1/2) ^j times θ0 (j = 1, 2,..., K), so that the viewpoint can be doubled with the interval kept substantially constant. However, the order in which the light deflection elements are stacked does not necessarily have to be in the order of the deflection angle.

  In the above example, the case where the number of positions deflected by the light deflecting means is 2, 4, and 8 has been described. However, by setting the time division number m of the input image to be equal to this deflection position, image breaks or brightness A good image without unevenness can be obtained. However, if the number of divisions is too large, the time for displaying an image at each position is shortened, and the image deteriorates unless an optical deflection element that operates sufficiently quickly is used.

FIG. 12 is a diagram showing a configuration in which the resolution of the observation position is increased.
In order to increase the observation position of the stereoscopic image, it is effective not only to increase the number of time divisions but also to increase the number of space divisions. FIG. 8 shows an example in which four images L1 to L4 are formed into two divided images. When the space division number L is 4 as shown in FIG. 6 and the time division number m is 2, the observation position can be 8 at maximum. Setting the observation position to m × L is the most efficient condition for securing a large number of observation positions. At this time, m × L input images n are prepared. Here, m and L need not be even numbers.
In FIG. 11, seven stereoscopic images are observed by aligning both eyes with (Ob.1 / Ob.2), (Ob.2 / Ob.3)... (Ob.7 / Ob.8). Although it has been shown that the position is obtained, it is possible to change the distance from the image display device to the observer as shown in FIG. The observation positions in this case are (Ob.9 / Ob.10), (Ob.10 / Ob.11), (Ob.11 / Ob.12), (Ob.13 / Ob.14), (Ob.14). /Ob.15) and (Ob.15 / Ob.16).
When this configuration is used, if the image is used as it is for the configuration of FIG. 11, the stereoscopic effect is enhanced and the image looks unnatural. In order to avoid this, it is necessary to capture an image at twice the density of the image of FIG. Specifically, the number of cameras installed is the same, but the interval between the cameras is halved. In this way, Ob. 9 / Ob. The image at the 10 observation positions appears as a normal stereoscopic image. Then, another stereoscopic image can be seen only by moving the observation position by half the eye width a, and the resolution of the observation position is increased.
As shown in FIG. 10, the timing of deflecting by the light deflecting means is extremely effective because it can reduce image blur at the time of light deflection by synchronizing with the image rewriting timing of the image display means.

FIG. 13 is a diagram for explaining the image rewriting direction of the image display means.
Regarding the image rewriting of the image display means, it is desirable that all the pixels are collectively performed. In the method of rewriting line-sequentially, it takes a long time until the last pixel is rewritten after the first pixel is rewritten. For this reason, for example, when the timing of light deflection is adjusted to the first pixel of rewriting, the last pixel is blurred, and conversely, when the timing is adjusted to the last pixel, the first pixel is blurred. When the line sequential rewrite image display means is used, it is desirable that the main scanning direction is the vertical direction, that is, the direction perpendicular to the light deflection direction.
In this case, for example, when the sub-scanning direction is from left to right, it is effective to reduce the above-mentioned image blur by configuring the light deflection to be from left to right in synchronization.
As the image display means, a direct-view display device such as a liquid crystal display, a plasma display, or an electroluminescence display, a projection liquid crystal display device, or a projection display such as a DLP can be used. In particular, in a direct view display device, a liquid crystal display is suitable. This is because each image division area of the image display means can be easily aligned with the image separation and condensing, and since a high-resolution one is commercially available compared to other direct-view display technologies, even when forming a three-dimensional image This is because higher resolution can be achieved.

FIG. 14 is a diagram showing a configuration of a stereoscopic image display device using a single-plate projection display device.
In the figure, reference numeral 42 is a light source, 43 is a screen, 44 is a diffusion plate, 45 is a condenser lens, 46 is LCOS as an image display means, 47 is a projection lens, 48 is a light source drive unit, 49 is an LCOS drive unit, and 50 is Each of the polarization beam splitters is shown.
In the projection display device, a display means using LCOS (Liquid Crystal On Silicon), which has a relatively fast rewriting speed and is advantageous for high resolution, is excellent. A stereoscopic image display device is configured using a single-plate projection display device as the image display means. In the figure, a light source 42 is a light source in which LEDs are arranged in a two-dimensional array. In the traveling direction of light emitted from the light source 42 toward the screen 43, a diffusion plate 44, a condenser lens 45, a polarizing beam splitter 50, An LCOS 46 as an image display element and a projection lens 47 as an optical member for observing the image pattern are sequentially arranged.
The illumination light that is controlled by the light source drive unit 48 and emitted from the light source 42 becomes uniform illumination light by the diffuser plate 44, and is controlled by the condenser lens 45 in synchronization with the illumination light source by the liquid crystal drive unit 49 to control the LCOS 46. Use critical lighting. The illumination light spatially modulated by the LCOS 46 is magnified by the projection lens 47 and projected onto the screen 43 as image light. The observer side of the screen 43 is provided with image separation means and light deflection means, and a stereoscopic image is formed as described above.

FIG. 15 is a diagram for explaining the configuration of the LCOS. FIG. 4A shows an example in which a microlens is prepared inside the LCOS, and FIG. 4B shows an example in which a micromirror is prepared inside the LCOS.
When attention is paid to the image division area in the image display means for displaying L3 and L4 in FIG. 8, all the emitted light from the image division area may be incident on the lens of the corresponding image separation means. A ghost image is generated. In order to prevent this, it is effective to provide an aperture control unit for each pixel of the image display means in advance. As shown in FIG. 15, the aperture control unit can be constituted by a microlens, a micromirror or the like provided in the LCOS. In particular, it is preferable that the conventional LCOS circuit unit is constituted by a microlens that can be used as it is.

FIG. 16 is a diagram illustrating a configuration example of the optical deflection element. FIG. 4A is a schematic side sectional view, and FIG. 4B is a partially enlarged view.
FIG. 17 is a diagram for explaining the behavior of the liquid crystal due to a change in applied voltage. FIG. 4A is a schematic diagram illustrating an optical path, and FIG. 4B is a schematic diagram illustrating changes in liquid crystal molecules.
FIG. 18 is a diagram illustrating a state in which vertically incident light to the light deflection element is deflected.
The configuration of the light deflection unit will be described.
A pair of transparent substrates having a sawtooth shape formed on at least one substrate, a liquid crystal layer comprising a chiral smectic C phase or a nematic phase between the pair of substrates, a transparent electrode for applying an electric field to the liquid crystal layer, and a transparent electrode Voltage application means (not shown) for changing the voltage application state. The shape of the formed sawtooth is formed so as to have a desired deflection amount and deflection direction. Since the alignment state of the liquid crystal changes depending on the voltage application condition, by setting the voltage application condition, the liquid crystal molecules can take two alignment states as shown in FIG.

  A change in the alignment state of the liquid crystal in the optical deflection element will be described with reference to FIG. Here, the configuration is similar to an optical deflection element using a liquid crystal composed of a homogeneously oriented chiral smectic C phase, but the orientation state of the liquid crystal changes depending on the voltage application condition, and the refractive index changes accordingly. For example, nematic liquid crystal can be used in the same configuration. On both sides of the liquid crystal, an electrode pair is formed by a pair of transparent solid electrodes that fill the liquid crystal and function as electric field applying means. By this electrode pair, an electric field is applied in a direction perpendicular to the homogeneously oriented liquid crystal director, that is, in the spontaneous polarization direction of the liquid crystal director. Furthermore, the inclined state is set so that the surface on the sawtooth-shaped substrate side forms an inclination ψ1 with respect to the normal direction of the incident light.

As shown in FIG. 6B, which shows a cross-sectional view taken along the line AA ′ in FIG. 6A, the liquid crystal director is aligned in two directions corresponding to the direction of the electric field from the electrode (the first alignment state and the first alignment state). 2 orientation state). In the light deflection element having such a configuration, it is possible to efficiently deflect incident light by regulating the orientation of the liquid crystal in a direction substantially orthogonal as shown in FIG. That is, when the incident light is manipulated so that the linear polarization direction of the incident light is in the Y-axis direction and is incident on this light deflecting element in the same figure, the liquid crystal director is directed in the Z-axis direction (first alignment state). An electric field is applied to the electrode by an electrode pair. In such a state, when the refractive index of the liquid crystal is equal to the refractive index of the substrate sandwiching the liquid crystal, the incident light behaves as ordinary light and passes through without being deflected. On the other hand, the direction of application of the electric field is reversed so that the liquid crystal director faces in a direction perpendicular to the direction (second alignment state). Here, the refractive index refers to a refractive index within a practical use temperature, for example, within a range of 10 ° C. to 60 ° C., within a suitable wavelength of visible light, for example, within a range of 435 nm to 700 nm. Indicates that the refractive index is equal under one condition in the range. In such a state, when the refractive index of the liquid crystal and the refractive index of the substrate sandwiching the liquid crystal are different, the incident light behaves as extraordinary light and is deflected by the difference in refractive index from the interface. In order to regulate the alignment of the liquid crystal in the orthogonal direction, the alignment films formed on the surfaces of both substrates are rubbed in the direction corresponding to the liquid crystal alignment, and the liquid crystal directors are oriented in a direction depending on the rubbing direction. The direction is strongly regulated. For the alignment treatment, a normal alignment film such as polyimide used for TN liquid crystal, STN liquid crystal or the like can be used. Moreover, it is preferable to perform a rubbing process or a photo-alignment process.
The characteristic of the optical deflection element having such a configuration is that the outgoing light with respect to the incident light can be rotationally moved by the control of the liquid crystal director. Therefore, a desired deflection amount can be obtained by appropriately selecting the distance between the light deflection element and the observation position.

16 to 18 are diagrams for explaining the structure and operation of the optical deflection element. In the case of obtaining the light traveling direction in the configuration of the light deflector as shown in FIG. 16, strictly speaking, each direction based on the refractive index ellipsoid based on both the direction of the liquid crystal director and the refractive indices no and ne with respect to the incident light traveling direction. The refractive index in the direction is obtained, and based on this, the light deflection direction is obtained. However, here, it is assumed that the refractive index no and the refractive index ne are switched easily depending on the alignment state of the liquid crystal, and according to Snell's law as shown in FIG. Is required).
In such a configuration of the light deflection means, it is only necessary to apply a voltage between the substrates, so that the light deflection means can be driven at a high speed with a low voltage.

FIG. 19 is a diagram showing another structural example of the optical deflection element.
The inner surface side cross-sections of both substrates (sawtooth-shaped substrate a, sawtooth-shaped substrate b) forming the light deflection element are formed in a sawtooth shape, and the inclined surfaces are inclined in directions symmetrical to each other with respect to the liquid crystal layer. The refractive index of the substrate, here, the refractive index of the sawtooth substrate a is set equal to the ordinary light refractive index no of the liquid crystal layer, and the refractive index of the other substrate (sawtooth substrate b) is set equal to the extraordinary light refractive index ne. . In the figure, incident light is linearly polarized light composed of an electric field vector that vibrates in a direction parallel to the paper surface. When entering the liquid crystal with the molecular long axis oriented in the vertical direction (corresponding to the first alignment state in FIG. 17), the refractive index is different at the interface between the sawtooth substrate a and the liquid crystal layer. The refractive index is equal at the interface with the shaped substrate b. For this reason, deflection occurs at the interface between the sawtooth substrate a and the liquid crystal layer, and the interface between the liquid crystal layer and the sawtooth substrate b goes straight while maintaining its direction. On the other hand, when the light enters the liquid crystal in the state where the molecular long axis is in the horizontal direction (corresponding to the second alignment state in FIG. 17), the refractive index is equal at the interface between the sawtooth substrate a and the liquid crystal layer, The refractive index is different at the interface with the sawtooth substrate b. Therefore, it goes straight without deflection at the interface between the sawtooth substrate a and the liquid crystal layer, and deflects at the interface between the liquid crystal layer and the sawtooth substrate b. The two deflection directions are symmetric with respect to the optical axis.

  If the period of the sawtooth shape formed on the sawtooth substrate does not correspond to the period formed by the image separation means, the display pixel line visually recognized at each position may pass through the sawtooth step portion. If the apex of the saw-tooth shape to be formed has a very acute angle, the influence of the step portion is small, but it is difficult to produce the apex of the saw-tooth shape at an acute angle, and generally the apex portion has a curvature. For this reason, there is a risk that light will diverge at the sawtooth-shaped stepped portion, and the image of the pixel line passing through the stepped portion will deteriorate. Therefore, by making the sawtooth-shaped period formed on the sawtooth-shaped substrate correspond to the period formed by the image separating means, it is possible to deflect light while avoiding the influence of the stepped portion. Although the structure and operation for deflecting light by the refractive index are described here, the refractive index no, ne of the liquid crystal and the pitch and height of the saw blade are appropriately set, so that only in one direction can be selectively set. Diffracted light can be obtained. By using this diffraction and switching the alignment state of the liquid crystal as described above, it is also possible to perform light deflection by switching between straight light and diffracted light.

<Production and operation of optical deflection element>
The quartz glass substrate was dry-etched to form a sawtooth shape having an inclination angle of about 0.5 ° and a pitch of 500 μm, and then ITO was sputtered on the sawtooth surface to a thickness of 2000 mm. Next, the polyimide alignment agent AL3046 is applied to a thickness of about 800 mm, and the substrate surface is rubbed under the condition that the stable direction in the homogeneous direction is perpendicular to the inclined direction of the inclined region (sawtooth direction). The orientation treatment was performed by the method. A glass substrate with ITO having a smooth surface was used as a counter substrate, and bonding was performed using an adhesive mixed with beads so that a portion with a small liquid crystal layer thickness was 1.5 μm. With the substrate heated to 90 degrees, a ferroelectric liquid crystal (Clariant R5002) is injected between the two substrates by the capillary method so that the injection direction follows the sawtooth shape, and the temperature from 70 ° C. to 55 ° C. is 20 V / μm. After being cooled in a state where a direct current voltage was applied, the optical deflection element shown in FIG. 16 was produced.
Next, a voltage is applied to the manufactured optical deflection element to operate it. As the applied voltage, a voltage of ± 10 V was applied using a function generator. The input waveform was a rectangular wave, and the voltage value was confirmed with a tester. The incident light to the element was white laser light having a diameter of about 1 mm and passed through a wavelength selection filter (588 nm) to set the wavelength of the incident light. Furthermore, a polarizing plate was installed between the element and the laser device, the direction of linearly polarized light was set to the sawtooth direction, and the light was incident on the sawtooth array position.
The element was operated in this way, and the transmitted light passing through the element was observed with a CCD camera. The CCD camera was installed at a distance of 1 m from the device. As a result, it was confirmed that the transmitted light was deflected by the voltage.

<Stereoscopic image observation>
A stereoscopic image display apparatus shown in FIG. 8 was produced using the above-mentioned light deflecting element, and the light deflecting element having the above-described configuration was installed as a light deflecting means between the lenticular lens and the observation position. A direct-view liquid crystal panel (1024 × 768 pixels) was used as the image display means. The pitch of the lenticular lens was 1.6 mm, and the curvature of the lenticular lens was selected so that a stereoscopic image was observed at a distance of about 2 m from the image display device. The interval between the observation positions (Ob. 1 to Ob. 4) was set to about 65 mm. The input image to the liquid crystal panel was performed by the method shown in FIG. Each camera was arranged at 9 cm intervals. The input signal to the liquid crystal panel and the timing of driving the optical deflection element were the same as in FIG. When the display image was observed by driving the light deflection element, a high-definition stereoscopic display image could be observed. By moving the viewpoint, we were able to observe stereoscopic images from three locations.

(Comparative Example 1)
A stereoscopic image display apparatus was manufactured with the configuration shown in FIG. As the image display means, a liquid crystal panel having the same resolution as in Example 1 was used. The left and right image signals were input to the liquid crystal panel to display an image. Next, a lenticular lens was used as the left and right image separating means. The lenticular lens has an opening interval of about 0.2 mm. When the distance between the liquid crystal panel and the lenticular lens was set 1.6 mm apart and the display image was observed from a position about 1 m away, a stereoscopic image could be observed. However, in Example 1, stereoscopic images could be observed at three places, but in this comparative example, only one place was observed.

  As shown in FIG. 11, a stereoscopic image display apparatus was configured using two sets of light deflection means. In the second set (observer side) of the light deflection element, the pitch of the saw blades was approximately doubled, and the light deflection angle was halved. By operating the curvature of the lenticular lens, observation was performed at a distance from Example 1, and the interval was set to 65 mm as in Example 1. A total of eight input images were set by adding a camera to the configuration of FIG. In spite of using the same image display means as in Example 1, four additional observation positions were obtained for the same high resolution image.

The stereoscopic image display apparatus shown in FIG. 14 was configured. The input image signal used in Example 1 was used. A type consisting of ferroelectric liquid crystal having a response speed of 1 ms or less was used for LCOS.
In a display image projected from such a single-plate projection type image display means, an extremely high-speed image rewriting is performed, so that a stereoscopic display image with higher definition and less blur is observed than the images shown in the first and second embodiments. did it.

The stereoscopic image display apparatus shown in Example 3 was configured, and a microlens was incorporated into the LCOS as shown in FIG.
In the display image projected from such a single-plate projection type image display means, each pixel on the screen is reduced and displayed, so that the ghost is reduced during the formation of the stereoscopic image, which is higher than the image shown in the third embodiment. A fine stereoscopic display image could be observed.

It is a figure for demonstrating the principle of a stereoscopic vision. It is a figure which shows an example of the method for seeing a different image with right and left eyes. It is a figure which shows the other example of the method for seeing a different image with right and left eyes. It is a figure which shows the example of the image display apparatus which raises the resolution by deflecting light by a time division. It is a figure for demonstrating the pixel visually recognized by the left and right eyes by repeating the display of FIG. It is an example of a stereoscopic display device in which four places are set as a plurality of observation positions. It is a conceptual diagram for demonstrating the production method of the stereo image shown in FIG. 1 is a schematic view of a stereoscopic image display device of the present invention. It is a conceptual diagram for demonstrating the production method of the stereo image shown in FIG. It is a timing chart which displays an image on the display apparatus shown in FIG. It is a figure which shows the example which used the optical deflection | deviation means for 2 steps | paragraphs. It is a figure which shows the structure which raised the resolution of the observation position. It is a figure for demonstrating the image rewriting direction of an image display means. It is a figure which shows the stereo image display apparatus structure using a single-plate-type projection type display apparatus. It is a figure for demonstrating the structure of LCOS. It is a figure which shows the structural example of an optical deflection | deviation element. It is a figure for demonstrating the behavior of the liquid crystal by the change of an applied voltage. It is a figure which shows a mode that the perpendicular | vertical incident light to an optical deflection element deflects. It is a figure which shows another structural example of an optical deflection | deviation element.

Explanation of symbols

42 Light source 43 Screen 46 Image display means

Claims (16)

Image display means arranged at a predetermined distance from a plurality of viewpoints, image separation means arranged on the viewpoint side with respect to the image display means, and image light transmitted through the image separation means for the plurality of viewpoints A plurality of input images formed corresponding to the plurality of viewpoints, wherein m and L are integers of 2 or more, respectively, and the number of space divisions is L. A stereoscopic image display device characterized by being spatially and temporally divided and displayed so that the number of time divisions is m . 2. The stereoscopic image display device according to claim 1, wherein when the width of each divided area on the image display means is d, the image separation means is periodically shaped or has a refractive index at a pitch Ds = L × d. Or a stereoscopic image display device characterized by having a structure in which the transmittance changes . 3. The stereoscopic image display device according to claim 1 , wherein the number of positions deflected by the light deflecting unit is m . 4. The stereoscopic image display device according to claim 1 , wherein when n input images formed corresponding to the plurality of viewpoints are n, the relationship is n = L × m. A featured stereoscopic image display device. 5. The stereoscopic image display device according to claim 1 , wherein a timing at which the deflection direction is switched by the light deflection unit is synchronized with an image rewriting timing of the image display unit. Image display device. 6. The stereoscopic image display device according to claim 1 , wherein a main scanning direction of the image display means is a vertical direction . 6. The stereoscopic image display device according to claim 1 , wherein the image rewriting timing of the image display means is collectively performed for all the pixels . The stereoscopic image display device according to any one of claims 1 to 7 , wherein the light deflection unit includes a pair of substrates having a region in which at least one inner surface side is inclined corresponding to the light deflection direction, A stereoscopic image display device comprising: a light deflection element having a liquid crystal layer composed of a smectic C phase or a nematic phase sandwiched between substrates and an electrode for applying a voltage to the liquid crystal layer . 9. The stereoscopic image display device according to claim 8 , wherein the inclined area is a sawtooth substrate formed in a sawtooth shape . 10. The stereoscopic image display device according to claim 1 , wherein there are a plurality of the light deflection elements, and a deflection angle of each of the light deflection elements is based on the light deflection element having the largest deflection angle. When the angle is θ0 and the number of added optical deflection elements is k (k ≧ 1), and the deflection angle of the jth optical deflection element is θj, θj = θ0 × (1/2) ^j (j = 1,... K), a stereoscopic image display device. The stereoscopic image display device according to any one of claims 1 to 10, wherein the image display means is a direct view type liquid crystal display device. 11. The stereoscopic image display device according to claim 1 , wherein the image display means is a projection type liquid crystal display device made of LCOS . The stereoscopic image display device according to any one of claims 1 to 10 , wherein the image display means is a projection type liquid crystal display device, and a size of a pixel to be projected is limited to a pixel pitch or less in a light valve. A stereoscopic image display device comprising an opening control unit for performing the operation . The stereoscopic image display apparatus according to claim 13 , wherein the aperture control unit is a microlens provided for each pixel . The stereoscopic image display apparatus according to claim 1 , wherein the image separating unit is a lenticular lens . 9. The light deflection element according to claim 8 , wherein the inner surfaces of both of the pair of substrates are sawtooth-shaped, and the inclined surfaces are inclined in directions symmetrical to each other with respect to the liquid crystal layer. An optical deflecting element, wherein the refractive index of the substrate is set to be equal to the ordinary light refractive index of the liquid crystal layer, and the refractive index of the other substrate is set to be equal to the extraordinary light refractive index .

Images