JP4272341B2 - Stereoscopic image display device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a stereoscopic image display device that displays a stereoscopic image.
[0002]
[Prior art]
Conventionally, many stereoscopic image display methods have been proposed. Among them, as a general stereoscopic image display method, there is a binocular stereoscopic display method as shown in FIG.
[0003]
As shown in FIG. 1, this binocular stereoscopic display method uses two parallax images, a left eye image 48 corresponding to the left eye 46 and a right eye image 49 corresponding to the right eye 47. In this method, the viewer wears polarized glasses or a polarization switching shutter 50 to present only the image corresponding to each eye and allow the viewer to recognize the reproduced stereoscopic image 51.
[0004]
This method has a feature that a stereoscopic image can be easily displayed with a relatively small amount of information. However, when a reproduced stereoscopic image 51 is observed by a human, the observation is based on the difference between the convergence distance 52 and the focal distance 53. There is a problem of causing visual fatigue in the elderly. This is a problem common to a method of displaying a stereoscopic image only by a method of presenting a parallax image.
[0005]
Here, in order to display a stereoscopic image with little visual fatigue, a method of reproducing a stereoscopic image in space is effective. Such methods include a hologram display method and a depth sampling method. Although this hologram display method has a possibility of realizing natural stereoscopic display, it requires interference fringe information of the subject and the amount of information becomes enormous, so an ultra-high-definition display device is required, and a moving stereoscopic image is displayed. There are many problems to display.
[0006]
On the other hand, in the depth sampling method, a two-dimensional sampled image at each depth position of an object is volumetrically displayed in space. In this method, a three-dimensional image having a depth is reproduced in a three-dimensional space, so that the convergence distance and the focal length match, thereby reducing visual fatigue on the observer, and even when the observer moves, it is natural. 3D images can be provided.
[0007]
This depth sampling method includes a varifocal mirror method that displays images on a vibrating mirror and displays a stereoscopic image, a moving screen method in which the screen moves mechanically at high speed, or a method that uses a rotating spiral screen. However, all of them are difficult to put into practical use due to the mechanical drive part.
[0008]
In addition, there is a half mirror composition method as a method of displaying a stereoscopic image by an apparatus having no mechanical drive part. In this method, a television monitor that is currently in practical use can be used, video display with relatively high image quality is possible, and there is no need for a special device, and the entire device configuration is simplified. A large number of display devices corresponding to gradations are necessary, and it is difficult to increase the number of depth gradations, and light loss due to a half mirror and an increase in the size of the device are problematic.
[0009]
In recent years, a method of displaying a depth-sampled stereoscopic image using a single two-dimensional image display device that does not have a mechanical drive unit has been proposed. FIG. 2 is a diagram for explaining a conventional depth sampling method using a liquid crystal focus variable lens. This conventional depth sampling method, as shown in FIG. 2, sequentially displays images 55 and 56 on a two-dimensional image display device 54, and a liquid crystal focus variable lens having a diameter of several centimeters or more arranged behind the image 55 and 56. In this method, the focal length of 57 is changed in synchronization with the display of the display image, the reproduced images 58 and 59 are displayed at different depth positions on the space, and the stereoscopic image is presented to the observer 60. The feature of this method is that the stereoscopic image display device does not require a mechanical drive part, and the observer does not need to wear special glasses, and can display a natural stereoscopic image.
[0010]
However, in the depth sampling display based on the time division method in which the depth images are sequentially switched at high speed, flicker is perceived by the observer unless the display of the stereoscopic image is completed within the afterimage time in human eyes. On the other hand, when the display time of one depth image is shortened, the brightness of the image is lowered. Further, a special display device that displays a large number of images corresponding to the number of depth gradations within a time period for displaying one image with a conventional video signal, that is, for example, 1/60 second is required.
[0011]
Here, the spatial division display method that reproduces the depth in pixel units solves the problem of depth sampling display in the time division method described above, and enables natural moving image stereoscopic image display with less visual fatigue. As an example of this space division method, there is a method of expressing the depth by individually changing the focal position by providing a small variable focus optical element for each pixel.
[0012]
However, this method requires a very advanced technique for manufacturing a large number of variable focus lenses that are equivalent to the number of pixels and for driving them. In addition, it is conceivable to use a liquid crystal lens as an element that can be electrically controlled with a large change in refractive index as a variable focus element. However, the currently proposed liquid crystal lens structure has a high drive voltage and a slow response speed. Is a problem.
[0013]
Furthermore, since the viewing angle depends on the relationship between the focal length of the variable focus lens provided in each pixel and the lens diameter, the extremely small size variable focus element corresponding to the pixel has a depth reproduction range of a stereoscopic image or The viewing angle is limited, and it seems difficult to realize a stereoscopic image display with a sense of depth.
[0014]
[Problems to be solved by the invention]
The present invention has been made to solve the above-described problem, and an object of the present invention is to provide a stereoscopic image display device that displays a high-quality stereoscopic image with a simple configuration without causing visual fatigue.
[0015]
[Means for Solving the Problems]
The above object is a stereoscopic image display device for displaying a stereoscopic image, The wavelength of the image display output light is determined according to the depth distance information of the display object, and the light having the wavelength is used. From the multiple pixels that make up the displayed 2D image , Independently for each pixel, any 2D image display means for outputting light having different wavelengths, and image forming means for forming an image of the light at different points according to the wavelength of the light The image forming means is a lens array in which wavelength dependent lenses including refractive lenses or wavelength dependent focal length variable lenses are arranged in an array. This is achieved by providing a stereoscopic image display device characterized by the above.
[0016]
According to such means, it is possible to display a stereoscopic image by forming light having different wavelengths output from the two-dimensional image displayed on the two-dimensional image display means at different points in the three-dimensional space. it can.
[0017]
Another object of the present invention is a stereoscopic image display device that displays a stereoscopic image, The wavelength of the image output light is determined according to the depth image information of the display object, and the light having the wavelength is used. From the multiple pixels that make up the displayed 2D image , A plurality of two-dimensional image display means for outputting light having different wavelengths with arbitrary intensities, and provided for each two-dimensional image display means, the light is imaged at different points according to the wavelength of light. Obtained by a plurality of imaging means and a plurality of imaging means respectively Painting Image synthesizing means for synthesizing images The color of the display object plane is reproduced as a color stereoscopic image by controlling the luminance ratio between the images reproduced at different depths by the light having different wavelengths. This is achieved by providing a stereoscopic image display device characterized by the above.
[0018]
According to such means, a stereoscopic image having an arbitrary color can be easily displayed by controlling the luminance ratio between the plurality of images synthesized by the image synthesizing means.
[0019]
Another object of the present invention is a stereoscopic image display device that displays a stereoscopic image, The wavelength of the image output light is determined according to the depth image information of the display object, and is displayed with light having the wavelength A plurality of two-dimensional images are switched and displayed at a predetermined time interval, and two-dimensional image display means for outputting light having different wavelengths from a plurality of pixels constituting the displayed two-dimensional image; Provided is a stereoscopic image display device characterized by comprising imaging means for imaging at different imaging points according to the wavelength and changing the position of the imaging point in synchronization with the switching display of the two-dimensional image Is achieved.
[0020]
According to such means, in order to change the position of the image formation point and the two-dimensional image displayed on the two-dimensional image display means at a predetermined time interval, any color can be obtained using the afterimage effect generated in human eyes. 3D images can be easily displayed.
[0021]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. In the drawings, the same reference numerals indicate the same or corresponding parts.
[0022]
The stereoscopic image display apparatus according to the embodiment of the present invention employs a new space division display method, and displays a stereoscopic image based on the depth information of the display object. That is, the stereoscopic image display device is different from the two-dimensional image display device that outputs and displays light of an arbitrary wavelength for each pixel in accordance with the depth distance information of the display object, and has a wavelength dependence that greatly differs in focal length depending on the light wavelength. A variable-focus optical system and displaying a stereoscopic image having a depth in space.
[0023]
That is, the wavelength of the image display output light is determined according to the depth distance information of the display object, and an image displayed with the light having the wavelength is created using an optical system having a different focal length depending on the wavelength of the light. Thus, a three-dimensional image can be displayed in the depth direction. In addition, a plurality of the devices are used to create an image of a display object, and by combining light of different wavelengths at each depth and changing the intensity ratio of each light, a color stereoscopic image that reproduces the color of the surface of the subject is obtained. Can be displayed.
[0024]
According to the stereoscopic image display device according to the embodiment of the present invention, the space division method for controlling the wavelength of output light for each pixel and reproducing the depth is adopted, so that a special high-speed image display device is not required, and time It is possible to solve flicker and brightness problems caused by the division method.
[0025]
In addition, according to the stereoscopic image display device according to the embodiment of the present invention, since a large number of display devices comparable to the depth gradation number are unnecessary, the device can be miniaturized. Furthermore, an image can be reproduced at an arbitrary position in the depth direction by continuously changing the wavelength.
[0026]
In addition, since the viewing area depends on the numerical aperture of the wavelength-dependent focus variable lens, the depth distance reproduction range and the viewing area can be reduced by using a lens with a large numerical aperture or a lens having a large numerical aperture. Both can be enlarged.
[0027]
Furthermore, according to the stereoscopic image display device according to the embodiment of the present invention, the conventional high-definition two-dimensional image display device can be used, and the filter function element capable of electrically selecting the wavelength and the chromatic aberration are large. A natural stereoscopic moving image can be displayed by combining with a wavelength-dependent variable focus optical system.
[0028]
Hereinafter, the stereoscopic image display apparatus according to the embodiment of the present invention will be described more specifically.
[Embodiment 1]
FIG. 3 is a diagram showing the stereoscopic image display apparatus according to Embodiment 1 of the present invention. As shown in FIG. 1, the stereoscopic image display device according to the first embodiment includes a filter control device 12, a two-dimensional image display device 1, and a wavelength dependent focus variable optical system 6. Here, the two-dimensional image display device 1 is connected to the filter control device 12.
[0029]
The two-dimensional image display device 1 outputs light having an arbitrary wavelength, and is composed of an element that is illuminated by, for example, a white light backlight and selectively transmits only an arbitrary wavelength for each pixel. . The two-dimensional image display device 1 is disposed after the two-dimensional image display device 1 by appropriately selecting, for example, the wavelength of the light 3 output from the pixel 2 and the wavelength of the light 5 output from the pixel 4. The light beams 3 and 5 transmitted through the wavelength-dependent variable focus optical system 6 are imaged at the imaging point 7 and the imaging point 8 having different depths as viewed from the observer 9. Based on such a principle, it is possible to display (present) a stereoscopic image 10 having a depth with respect to the observer 9.
[0030]
Further, the filter control device 12 selects the wavelength of light output from each pixel by controlling the output light wavelength filter of the two-dimensional image display device 1 according to the supplied depth distance information. Here, the depth distance information 11 is a distance value obtained by actually photographing a subject with an imaging device having a distance detection function, or a distance value artificially obtained by computer graphics or the like.
[0031]
Below, the said two-dimensional image display apparatus 1 is demonstrated concretely.
[0032]
In general, as an optical bandpass filter, there is a lyo-filter that obtains a sharp transmission spectrum of a specific wavelength by laminating a large number of birefringent plates sandwiched between two polarizers. A wavelength tunable bandpass filter can be configured by using a medium that electrically changes the birefringence effect as the birefringent plate used in this filter. Here, for example, by using a liquid crystal that electrically changes the birefringence effect as a medium, a wavelength tunable bandpass filter that can electrically select a wavelength can be configured.
[0033]
Such a liquid crystal variable lyo filter is arranged in an array so as to correspond to each pixel of the two-dimensional image display device, and by providing a control device that individually controls the pixel, light having an arbitrary wavelength can be obtained. It is possible to output for each pixel.
[0034]
FIG. 4 is a diagram illustrating a configuration example of the two-dimensional image display device 1 illustrated in FIG. 3. As shown in FIG. 4, the two-dimensional image display device 1 includes a light emitter 22, an image display unit 24, and a wavelength tunable filter element 25, and the wavelength tunable filter element 25 includes a plurality of parallel polarizing plates 26. including.
[0035]
Here, the image display unit 24 is provided to face the light emitter 22, and the wavelength tunable filter element 25 is disposed on the output side of the image display unit 24. In the two-dimensional image display device 1 having such a configuration, white light 23 having a wavelength in the visible light region output from the light emitter 22 is input to the image display unit 24 that displays a luminance image and intensity-modulated. .
[0036]
The “intensity modulation” means that a portion where the luminance of the subject video is high is bright and a portion where the luminance is low is dark. Therefore, the intensity modulation results in the same modulation as that when creating a monochrome television image. In this “intensity modulation”, the intensity of the transmitted light is controlled by changing the transmittance of the incident white light. For example, as in the case of a liquid crystal panel sandwiched between polarizing plates, The amount of transmitted light incident from is controlled.
[0037]
Here, the image display unit 24 shown in FIG. 4 can be configured by a transmissive liquid crystal panel. The white light intensity-modulated as described above in the image display unit 24 is input to the wavelength tunable filter element 25 that selects an arbitrary wavelength. Here, the wavelength tunable filter element 25 has a structure in which a plurality of electrically driven liquid crystal display devices 27 sandwiched between two flat polarizing plates 26 are stacked.
[0038]
The pixels of the image display unit 24 and the pixels of the plurality of electrically driven liquid crystal display devices 27 have the same arrangement, number, and size, and the wavelength of transmitted light can be selected independently for each pixel. Is done. That is, white light incident on the wavelength tunable filter element 25 is transmitted with a transmittance depending on the wavelength in each polarizing plate 26 and each electrically driven liquid crystal display device 27. By setting different values in the electrically driven liquid crystal display device 27, it is possible to selectively transmit only the light 28 having a desired wavelength independently in each pixel.
[0039]
Further, when the electrically driven liquid crystal display device 27 sandwiched between the polarizing plates 26 is stacked, the thickness increases, so that the light beam output from the image display unit 24 has a spread and passes through the wavelength tunable filter 25. Crosstalk occurs between the pixels, but the corresponding pixels between the electrically driven liquid crystal display devices 27 are connected by fibers, microlenses, or the like, so that the light can be prevented from spreading in the lateral direction.
[0040]
FIG. 5 is a diagram showing another configuration of the two-dimensional image display device 1 shown in FIG. As shown in FIG. 5, the two-dimensional image display device 1 a has the same configuration as the two-dimensional image display device 1 shown in FIG. 4, but includes a wavelength variable filter element 29 instead of the wavelength variable filter element 25. It is different in point.
[0041]
Here, the image display unit 24 shown in FIG. 5 displays a luminance gradation image in the same manner as the image display unit 24 shown in FIG. 4, and the light output from the image display unit 24 selects an arbitrary wavelength. Is input to the tunable filter element 29.
[0042]
On the other hand, the wavelength tunable filter element 29 has a configuration in which a medium 30 in which the birefringence effect is electrically changed is sandwiched between two parallel flat substrates 31 with electrodes and has a high luminous flux interference. Configure the system. Here, for example, liquid crystal can be used as the medium, and light 28 having an arbitrary wavelength is selectively output by changing the birefringence effect by an electric means such as changing the applied voltage. Can do.
[0043]
As the substrate 31, for example, a glass substrate having a high surface accuracy deposited with a metal film of silver or aluminum, or a substrate having a high reflective characteristic by depositing a dielectric in multiple layers (so-called etalon) is used. be able to.
[0044]
FIG. 6 is a diagram showing still another configuration of the two-dimensional image display device 1 shown in FIG. As shown in FIG. 6, the two-dimensional image display device 1b includes a light emitter 22, a spectroscopic optical system 32, a lens array 34, and a filter device 36. The filter device 36 has a plurality of sub-pixels corresponding to each pixel. Pixel 37 is included.
[0045]
In the two-dimensional image display device 1b having the above-described configuration, white light 23 having a wavelength in the visible light region is output from the light emitter 22, and the white light 23 is light having a different wavelength by the spectroscopic optical system 32. Each is spatially separated, and a spectrum 33 is formed.
[0046]
Note that the spectroscopic optical system 32 has a prism that uses the wavelength dependency of the refractive index, a diffraction grating that uses the wavelength dependency of the diffraction angle, or a spatially wavelength-dependent transmittance characteristic distribution. An interference filter or the like can be used.
[0047]
Further, based on the spatially separated spectrum 33, the lens array 34 creates an image 35 at a ratio of at least one for each pixel. The image 35 is also an image that is spatially dispersed in the same manner as the light dispersed by the spectroscopic optical system 32, that is, an image in which light spreads in rainbow colors from red to blue. Here, in order to extract light 28 having a specific wavelength from such an image 35, only a part of the light forming the image 35 needs to be selectively transmitted.
[0048]
That is, in the filter device 36, only a part of the subpixels 37 is set in a transmission state for each pixel among the plurality of subpixels 37 constituting one pixel, and the other subpixels 37 are set in a state of not transmitting light. Accordingly, by selecting the position of the sub-pixel 37 that transmits light for each pixel, it is possible to output light 28 having a desired wavelength for each pixel.
[0049]
In the following, the wavelength dependent focus variable optical system 6 shown in FIG. 3 will be described in detail. As the wavelength-dependent variable focus optical system 6 according to the first embodiment, a refractive lens having a large wavelength dependency can be used. Here, the wavelength dependence of the focal length can be increased by selecting a material having a large refractive index change depending on the wavelength as the refractive lens.
[0050]
As a material constituting the refractive lens, a material having a small Abbe number, that is, a material having a high dispersion characteristic with a large refractive index change with respect to the wavelength is suitable. For example, heavy titanium flint, heavy flint, heavy lanthanum flint And optical glass materials such as lanthanum flint.
[0051]
In addition, in the reflection or transmission type diffractive lens using the light diffraction phenomenon, the wavelength dependence of the focal length is proportional to the reciprocal of the wavelength, so that the wavelength dependence of a relatively large focal length can be easily realized. Can do.
[0052]
Here, a trial calculation as to how much focal length dependence can be obtained by the diffractive lens is shown. First, the relationship between the focal length f of the diffractive lens and the wavelength λ is expressed by the following equation (1). Note that a is a constant.
f = a / λ (1)
At this time, for example, when a lens having a wavelength of 632.8 nm and a focal length of 0.8 m is used, the focal length f at a short wavelength of 400 nm in the visible wavelength region is used. ₄₀₀ Is calculated by the following equation (2).
f ₄₀₀ = 632.8 × 10 ^-9 × 800 × 10 ^-3 / 400 × 10 ^-9 = 1.26m (2)
In addition, the focal length f at a long wavelength of 700 nm in the visible wavelength region ₇₀₀ Is similarly calculated by the following equation (3).
f ₇₀₀ = 632.8 × 10 ^-9 × 800 × 10 ^-3 / 700 × 10 ^-9 = 0.72m (3)
Accordingly, the change Δf in the focal length in the visible wavelength region is calculated by the following equation (4).
Δf = f ₄₀₀ -F ₇₀₀ = 1.26−0.72 = 0.54m (4)
This shows that a very large change in focal length can be obtained.
[0053]
Further, as the diffractive optical element, a holographic optical element in which interference fringes are recorded by a laser beam, an electron beam drawing apparatus or the like can be used. The lens as the holographic element can be easily produced simply by causing the laser beam to interfere with it and recording it on a hologram dry plate or film, and a lens having a size of several tens of cm or more can be produced. In order to avoid the influence of 0th-order or higher-order diffracted light when the holographic element lens is used, it is also effective to make the optical axes of the reference light and the object light shifted.
[0054]
Also, binary optics formed with a binary phase pattern by a lithography method can be used for the wavelength-dependent variable focus optical system. The binary optical element is a step-like lens formed by a series of procedures such as mask alignment and exposure, development, etching, and resist removal like an electronic integrated circuit, and can be manufactured relatively easily. The diffraction efficiency can be increased by repeating the manufacturing process a plurality of times to increase the number of phase steps.
[0055]
In particular, since a phase type zone plate (kinoform) lens can obtain a high diffraction efficiency, a bright image can be displayed and the influence of 0th-order or higher-order diffracted light can be kept low.
[0056]
In addition, by providing a lens having a large wavelength dependency in multiple stages, a large focal length wavelength dependency can be obtained. Of course, as the wavelength-dependent lens, a hybrid lens in which a refractive lens and a diffractive lens are combined can also be used.
[0057]
FIG. 7 is a diagram showing an example of the wavelength dependent focus variable optical system 6 shown in FIG. The wavelength-dependent variable focus optical system 6 needs to be large enough to image the screen of the two-dimensional image display device 1, that is, a lens having a large diameter. Such a lens is expensive and difficult to manufacture. Therefore, in order to display a large image, the image forming optical system 6a may be configured using lens arrays 39 and 40 in which minute wavelength-dependent variable focal length lenses are arranged in an array as shown in FIG. .
[0058]
Here, as shown in FIG. 7, the light output from the two-dimensional image display device 1 is imaged by the lens arrays 39 and 40, thereby generating a stereoscopic image 10 having a depth. At this time, as shown in FIG. 8, the distance between the image 63 displayed on the two-dimensional image display device 1 and the lens array 39 is set to twice the central focal length f of the focal length variable range, and two lenses are used. By setting the distance between the arrays 39 and 40 to be four times the central focal length f, a reproduced image 61 that is approximately the same size as the image 63 at a position away from the lens array 40 by twice the central focal length f. Can be obtained.
[0059]
In the above, “center focal length” means a focal length near the center of a variable range in which the focal length changes. For example, when visible light having a wavelength of 400 nm to 700 nm is used for image display, assuming that the focal length for the wavelength 400 nm is f1 and the focal length for the wavelength 700 nm is f2, the “center focal length f” is (f1 + f2) / 2. Means the value of If the lens arrays 39 and 40 are arranged as shown in FIG. 8, the imaging optical system in which the original image and the reproduced image have a one-to-one relationship does not greatly fail even when the focal length is changed.
[0060]
In addition, as the minute wavelength-dependent variable focus lens constituting the lens arrays 39 and 40, the above-described refractive and diffractive lenses can be used, and a distributed refractive index lens can also be used. Here, a normal lens has a constant refractive index of the medium and brings about an imaging action by a change in the thickness of the lens. On the other hand, the distributed refractive index lens has a constant thickness of the medium from the optical axis at the center of the medium. By having a refractive index distribution corresponding to the distance in the radial direction, an image forming action is brought about.
[0061]
FIG. 9 is a diagram showing an example of such a distributed refractive index lens. As shown in FIG. 9, the distributed refractive index lens is composed of a relatively short rod-shaped plastic or glass, and is configured such that the refractive index decreases as the distance from the center (optical axis 66) of the rod increases. The Accordingly, the central portion 65 in the vicinity of the optical axis 66 has a higher refractive index than the outer peripheral portion 64. As shown in FIG. 9, an image 63b is obtained from the image 63 by the distributed refractive index lens having the above configuration.
[0062]
As described above, by configuring the wavelength-dependent variable focus optical system 6 with the lens arrays 39 and 40, an optical system capable of displaying a large image can be easily configured.
[0063]
FIG. 10 is a diagram showing another example of the wavelength dependent variable focus optical system 6 shown in FIG. When a three-dimensional image is formed by a single wavelength-dependent focal length variable lens, the imaging magnification varies greatly depending on the depth position, and image distortion around the image also increases. Therefore, even when the depths are different, the variable wavelength focal length variable lens and the plurality of lenses are combined as shown in FIG. It is good to configure.
[0064]
That is, as shown in FIG. 10, the wavelength-dependent variable focal length optical system 6b is a combination of the first lens system 41 and the wavelength-dependent variable focal length lens or a combination of the wavelength-dependent variable focal length lens and another lens. The second lens system 42 and the third lens system 43 are configured.
[0065]
Then, the light output from the pixel 2 of the two-dimensional image display device 1 is incident on the first lens system 41 disposed at a position where the focal length is f1 and is separated from the two-dimensional image display device 1 by the distance f1. It is supplied to a second lens system 42 disposed at a position separated from the one lens system 41 by a distance f1. Furthermore, the light output from the second lens system 42 is incident on the third lens system 43 disposed at a position where the focal length is f2 and is separated from the second lens system 42 by the distance f2. Accordingly, the sizes of the images 44 and 45 formed at different depths as viewed from the observer 9 according to the wavelength can be made almost uniform, and distortion of the images 44 and 45 can be reduced.
[0066]
As described above, according to the stereoscopic image display device according to Embodiment 1 of the present invention, the light having different wavelengths selected in the two-dimensional image display device 1 is used by using the wavelength-dependent variable focus optical system 6. Since a stereoscopic image is displayed by forming an image on a point having a different depth as viewed from the observer, a stereoscopic image that is less likely to cause visual fatigue than a stereoscopic display by a parallax image and that allows natural stereoscopic vision is provided. It can be displayed with a simple configuration.
[0067]
Further, according to the stereoscopic image display apparatus according to Embodiment 1 of the present invention, an observer can view a stereoscopic image without wearing special glasses, and stereoscopically view in both the horizontal direction and the vertical direction. be able to.
[0068]
In addition, according to the stereoscopic image display device according to Embodiment 1 of the present invention, various two-dimensional image display devices can be used. Furthermore, since the stereoscopic image display apparatus performs depth sampling if the light is spatially divided, it is not necessary to display a large number of images corresponding to the number of depth gradations required for time-division display at a high speed. An image can be displayed.
[0069]
In addition, according to the stereoscopic image display apparatus according to Embodiment 1 of the present invention, it is possible to display a stereoscopic image that has a large viewing angle and is observable by a plurality of observers. Furthermore, since the information required in the stereoscopic image display according to the first embodiment is two-dimensional image information and depth distance information, even when the display object (subject) is moving, A stereoscopic image can be displayed. Further, since the amount of the information required for displaying the stereoscopic image is small, the transmission of the information in the display can be easily performed.
[Embodiment 2]
The stereoscopic image display apparatus according to Embodiment 2 of the present invention displays an image by light having different wavelengths by time division, and displays a stereoscopic image by changing the transmittance of the image display apparatus in accordance with the display timing. To do. Hereinafter, the stereoscopic image display apparatus according to the second embodiment will be specifically described.
[0070]
FIG. 11 is a diagram showing a configuration of a stereoscopic image display apparatus according to Embodiment 2 of the present invention. As shown in FIG. 11, the stereoscopic image display apparatus includes a two-dimensional image display apparatus 1, a wavelength dependent focus variable optical system 6, a light emitter 22 and optical systems 100, 101, 104, a reflector 102, and a spectroscopic optical element. 38 and an aperture 103.
[0071]
In the stereoscopic image display apparatus according to the second embodiment shown in FIG. 11, first, the light emitter 22 outputs light 23 having a wavelength in the visible light region. The light 23 is converted into parallel light by the optical system 100 and is incident on the spectroscopic optical element 38 formed of a diffraction grating or a prism.
[0072]
Furthermore, the light reflected or transmitted by the spectroscopic optical element 38 is condensed by the optical system 101 at different positions for each wavelength. Here, since a reflecting mirror 102 such as a galvanometer mirror or a polygon mirror that can change the tilt angle of the surface at high speed is disposed between the optical system 101 and the condensing point, the light is reflected by the reflecting mirror 102. Reflected.
[0073]
Further, an aperture 103 is provided at a position where the light is collected, and only light having a specific wavelength is selectively transmitted. At this time, each wavelength can be sequentially transmitted in a short time by changing the angle of the reflecting surface of the reflecting mirror 102 with respect to the incident light at high speed.
[0074]
The light transmitted through the aperture 103 is incident on the secondary image display device 1 through the optical system 104. At this time, the secondary image display apparatus 1 displays the stereoscopic image 10 in the depth direction via the wavelength-dependent variable focus optical system 6 by switching the display image in synchronization with the wavelength change of the supplied light.
[0075]
As described above, according to the stereoscopic image display apparatus according to Embodiment 2 of the present invention, light having an arbitrary wavelength can be selected from white light by a simple optical system, and light absorption such as a polarizing plate is large in wavelength selection. Since no component is required, light utilization efficiency can be increased. Therefore, by using a high-output light source, it is possible to obtain an image with high-luminance light.
[0076]
Further, if the rotation speed of the reflecting mirror 102 is increased, the wavelength scanning can be easily increased. In the above, the reflecting mirror 102 may be fixed, and the spectroscopic optical element 38 itself may be changed in angle at high speed instead of the reflecting mirror 102.
[0077]
In addition, the stereoscopic image display apparatus according to the second embodiment temporally spectrally separates the light using the spectroscopic optical element 38, the reflecting mirror 102, the aperture 103, and the like as described above. It is possible to substitute one variable bandpass filter that selects a transmission wavelength using a medium that can change the frequency.
[0078]
In this case, since light is transmitted through the polarizing plate and the liquid crystal cell, it is difficult to make powerful light incident on the two-dimensional image display device 1, but by controlling the applied voltage, an arbitrary wavelength can be set. Since the held light can be supplied to the two-dimensional image display device 1 while switching at high speed, a mechanical drive unit such as a rotating mirror is not necessary, and the scale of the stereoscopic image display device can be greatly reduced. it can.
[Embodiment 3]
FIG. 12 is a diagram showing a configuration of a stereoscopic image display apparatus according to Embodiment 3 of the present invention. As shown in FIG. 12, the stereoscopic image display apparatus according to the third embodiment includes two-dimensional image display apparatuses 13, 15, and 17, wavelength-dependent focus variable optical systems 14, 16, and 18, and an image synthesis optical system. 19 is provided. Here, the wavelength-dependent variable focus optical systems 14, 16, and 18 are provided between the two-dimensional image display devices 13, 15, and 17 and the image synthesis optical system 19, respectively.
[0079]
The stereoscopic image display apparatus having such a configuration uses a plurality of stereoscopic image display apparatuses according to the first embodiment, and displays the color stereoscopic image 20 by combining the display images.
[0080]
More specifically, since the three-dimensional image reproduced by the two-dimensional image display device 13 and the wavelength-dependent variable focal length optical system 14 has a different wavelength in the depth distance direction, an image having a different color for each depth distance is displayed. The surface color of the object cannot be reproduced. Therefore, in order to display a color stereoscopic image faithful to the display object, images and images reproduced by the other two-dimensional image display devices 15 and 17 and the corresponding wavelength-dependent focus variable optical systems 16 and 18 are displayed. The color is combined in the combining optical system 19 and a color stereoscopic image 20 is displayed.
[0081]
Here, in the above-described image synthesis, the wavelength-dependent focus variable optical systems 14, 16, and 18 have different focal length dependencies with respect to the wavelength, or are reproduced with the two-dimensional image display devices 13, 15, and 17. By sequentially adding an optical path difference to the optical distance between the three-dimensional images, images with light having different wavelengths are reproduced at positions having different depths. Then, the color of the display object surface can be reproduced as the color stereoscopic image 20 by controlling the luminance ratio between the images displayed by light having different wavelengths. Note that the above-described image composition can be easily realized by an image composition optical system 19 including a plurality of half mirrors as shown in FIG.
[0082]
As described above, according to the stereoscopic image display apparatus according to Embodiment 3 of the present invention, a color stereoscopic image that reproduces the display object including the surface color can be easily generated.
[Embodiment 4]
The stereoscopic image display device according to the fourth embodiment of the present invention uses the stereoscopic image display device according to the first embodiment to display a plurality of stereoscopic images at high speeds at different depth distances every time. A stereoscopic image is displayed.
[0083]
That is, the three-dimensional image reproduced by the two-dimensional image display device 1 and the wavelength-dependent variable focus optical system 6 has a different wavelength in the depth distance direction, so the color of the image differs for each distance, and the color of the surface of the display object. Cannot be reproduced.
[0084]
Therefore, in the stereoscopic image display device according to the fourth embodiment, as shown in FIG. 13, the focal length is controlled by electrical control such as controlling the applied voltage in order to enable color display of the display object. The variable focus optical element 21 that can adjust the speed at high speed is used. Hereinafter, the operation of the stereoscopic image display apparatus according to the fourth embodiment will be described with reference to FIG.
[0085]
As shown in FIG. 14, for example, at time T1, the applied voltage of the variable focus optical element 21 is set to voltage V1, voltage V2 at time T2, voltage V3 at time T3, and voltage V4 at time T4. The imaging position of the image reproduced by the dependent variable focus optical system 6 is shifted in the depth direction with time. Thereby, it is possible to display images having different wavelengths at positions where the depth distance z is different as viewed from the observer 9.
[0086]
The color display in the conventional video image is realized by changing the luminance ratio of the R, G, B primary color images to be combined, but the above method similarly has each color at each depth distance. The focal length of the variable focus optical element 21 is changed so that at least three images are combined. Then, the color of the surface of the expression object can be reproduced by controlling the luminance ratio between the images by light having at least three or more different wavelengths.
[0087]
A specific example will be described below with reference to FIG. Here, as shown in the frame of FIG. 15D, a case where a white ball, a yellow lemon, and a red apple are displayed as stereoscopic images G1, G2, and G3, respectively, will be described as an example.
[0088]
As shown in FIG. 15A, when the voltage applied to the variable focus optical element 21 is the voltage V1 at time T1, the length of the visible range of the light constituting the image displayed on the two-dimensional image display device 1 is increased. The light of the wavelength is imaged at the position D1a, and the light of the short wavelength is imaged at the position D1b. Further, as shown in FIG. 15B, when the voltage applied to the variable focus optical element 21 is the voltage V2 at time T2, the focal length changes, so that the light having a long wavelength in the visible range is positioned at the position D2a, The short wavelength light is imaged at a position D2b. As shown in FIG. 15 (c), when the voltage applied to the variable focus optical element 21 is the voltage V3 at time T3, the focal length changes in the same manner as described above. The light at the position D3a and the short wavelength is imaged at the position D3b.
[0089]
Then, in order to reproduce the depth distance z and the color of the display object, the wavelength and brightness of the output light are controlled in synchronization with the switching of the applied voltage in the variable focus optical element 21 as described above. The two-dimensional image is switched and displayed on the two-dimensional image display device 1. Here, as an example of this switching display, when displaying the white ball, an image having a wavelength corresponding to the depth distance for reproducing the ball, that is, the time T1 when the voltage V1 is applied to the variable focus optical element 21. Then, a red image G1r is displayed as a green image G1g at time T2 when the voltage V2 is applied, and a blue image G1b at time T3 when the voltage V3 is applied.
[0090]
Then, the luminance ratio between the red image G1r, the green image G1g, and the blue image G1b is controlled and switched at a high speed, and the white color that is the color of the surface of the ball is displayed as a stereoscopic image. By the same method, it is possible to simultaneously display a stereoscopic image G2 that displays a yellow lemon and a stereoscopic image G3 that displays a red apple at positions where the depth distance z is different.
[0091]
FIG. 15 shows an example in which the applied voltage in the variable focus optical element 21 is changed in three stages at times T1, T2, and T3, and the images formed in time series are multiplexed and synthesized. By changing the applied voltage in more stages, it is possible to reproduce the color of the surface of the display object in a wide range in the depth direction.
[0092]
Here, as the variable focus optical element 21, it is possible to use a variable focus liquid crystal lens whose focal length changes according to the voltage applied as described above. The variable focus liquid crystal lens includes a lens-shaped electrode substrate 69 with a liquid crystal 67 interposed therebetween and a curvature as shown in FIG. 16A, or as shown in FIG. 16B. A liquid crystal is sandwiched by a substrate having a hole-shaped transparent electrode 68 or a ring-shaped transparent electrode 71 shown in FIG. 16C, and an electric field applied to the liquid crystal is controlled to have a refractive index distribution. There is.
[0093]
On the other hand, in the above, the wavelength-dependent variable focal length optical system 6 and the variable focal length optical element 21 are independent elements. However, if a liquid crystal focal length variable element having a wavelength dependent focal variable optical element on a substrate is used. The focal length can be changed depending on the wavelength of light, and the focal length can be changed by controlling the applied voltage.
[0094]
Here, for example, as the liquid crystal focal length variable element, as shown in FIG. 17, a transparent electrode 77 is provided on a diffractive lens-like substrate 73 having a large wavelength dependency of the focal length, and a substrate 75 with a transparent electrode is used as a counter substrate. A diffractive liquid crystal focus variable lens 79 in which a liquid crystal 67 is sandwiched between a diffractive lens-like substrate 73 provided with a transparent electrode 77 and a substrate 75 with a transparent electrode can be used.
[0095]
Further, as shown in FIG. 18, such a diffractive liquid crystal focus variable lens 79 has a different focal length depending on the wavelength of incident light and can also change the focal length by controlling the applied voltage. .
[0096]
As described above, the stereoscopic image display apparatus according to Embodiment 4 of the present invention can also easily generate a color stereoscopic image that reproduces the display object including the surface color.
【The invention's effect】
As described above, according to the stereoscopic image display apparatus according to the present invention, the light having different wavelengths output from the two-dimensional image displayed on the two-dimensional image display means is formed at different points in the three-dimensional space. Since a stereoscopic image can be displayed, a high-quality stereoscopic image can be obtained with a simple configuration with little visual fatigue.
[0097]
In addition, according to the stereoscopic image display device according to the present invention including the image synthesizing means, a stereoscopic image having an arbitrary color can be easily displayed by controlling the luminance ratio between the plurality of synthesized images. Therefore, the color of the display object can be easily reproduced as a stereoscopic image.
[0098]
In addition, according to the stereoscopic image display apparatus according to the present invention that changes the position of the image formation point in synchronization with the switching display of a plurality of two-dimensional images, it has an arbitrary color using the afterimage effect that occurs in human eyes. Since the stereoscopic image can be easily displayed, various color stereoscopic images that reproduce the display object can be easily displayed.
[Brief description of the drawings]
FIG. 1 is a diagram illustrating a conventional binocular stereoscopic display method.
FIG. 2 is a diagram for explaining a conventional time-division depth sampling stereoscopic display method using a liquid crystal focus variable lens.
FIG. 3 is a diagram showing a stereoscopic image display apparatus according to Embodiment 1 of the present invention.
4 is a diagram showing a configuration of the two-dimensional image display device shown in FIG. 3;
FIG. 5 is a diagram showing another configuration of the two-dimensional image display device shown in FIG. 3;
6 is a diagram showing still another configuration of the two-dimensional image display device shown in FIG. 3. FIG.
7 is a diagram showing an example of the wavelength dependent focus variable optical system shown in FIG. 3; FIG.
FIG. 8 is a diagram showing a one-to-one imaging optical system using a microlens array.
FIG. 9 is a diagram illustrating an example of a distributed refractive index lens.
10 is a diagram showing another example of the wavelength dependent variable focal length optical system shown in FIG. 3;
FIG. 11 is a diagram showing a configuration of a stereoscopic image display apparatus according to Embodiment 2 of the present invention.
FIG. 12 is a diagram showing a configuration of a stereoscopic image display apparatus according to Embodiment 3 of the present invention.
FIG. 13 is a diagram showing a configuration of a stereoscopic image display apparatus according to Embodiment 4 of the present invention.
14 is a diagram for explaining the operation of the stereoscopic image display apparatus shown in FIG.
15 is a diagram illustrating a specific operation of the stereoscopic image display device illustrated in FIG.
FIG. 16 is a diagram illustrating an example of a liquid crystal focus variable lens.
FIG. 17 is a diagram illustrating another example of a liquid crystal focus variable lens.
18 is a diagram for explaining the operation of the liquid crystal variable lens shown in FIG. 17;
[Explanation of symbols]
1, 1a, 1b, 13, 15, 17, 54 Two-dimensional image display device
6, 6b, 14, 16, 18 Wavelength-dependent focus variable optical system
6a Image imaging optical system
12 Filter control device
19 Image synthesis optical system
21 Variable focus optical element
22 Luminescent body
24 Image display
25, 29 Tunable filter element
26 Polarizing plate
27 Electric drive type liquid crystal display device
30 medium
31, 69, 73, 75 substrate
32 Spectral optics
34, 39, 40 Lens array
36 Filter device
37 subpixels
38 Spectroscopic optical element
41 First lens system
42 Second lens system
43 Third lens system
50 Polarized glasses or polarization switching shutter
57 LCD focus variable lens
67 LCD
68, 71, 77 Transparent electrode
79 Diffractive liquid crystal focus variable lens
100, 101, 104 optical system
102 Reflector
103 aperture

Claims (3)

A stereoscopic image display device for displaying a stereoscopic image,
The wavelength of the image display output light is determined according to the depth distance information of the display object, and an arbitrary wavelength is independently and independently selected from each of the plurality of pixels constituting the two-dimensional image displayed with the light having the wavelength. Two-dimensional image display means for outputting the light with
An imaging means for imaging the light at different points according to the arbitrary wavelength ;
A stereoscopic image display device , wherein the imaging means is a wavelength-dependent lens including a refractive lens or a lens array in which wavelength-dependent focal length variable lenses are arranged in an array . A stereoscopic image display device for displaying a stereoscopic image,
The wavelength of the image output light determined according to the depth image information of the display object, a plurality of pixels constituting the two-dimensional image displayed with light having a wavelength, outputs the light having different wavelengths in an arbitrary intensity A plurality of two-dimensional image display means,
A plurality of imaging means provided corresponding to each of the two-dimensional image display means, and imaging the light at different points according to the wavelength of the light;
And an image synthesizing means for synthesizing images obtained respectively by the plurality of imaging means,
A stereoscopic image display device that reproduces the color of the display object plane as a color stereoscopic image by controlling a luminance ratio between the images reproduced at different depths by the light having different wavelengths. . A stereoscopic image display device for displaying a stereoscopic image,
The wavelength of the image output light is determined according to the depth image information of the display object, and a plurality of two-dimensional images displayed with the light having the wavelength are switched and displayed at predetermined time intervals, and the displayed two-dimensional image Two-dimensional image display means for outputting light having different wavelengths from a plurality of pixels constituting
Imaging means for imaging the light at different imaging points in accordance with the wavelength of the light and changing the position of the imaging point in synchronization with the switching display of the two-dimensional image; A featured stereoscopic image display device.

Images