JP2838163B2 - How to display dynamic 3D images - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a method for displaying a dynamic three-dimensional image with parallax.

2. Description of the Related Art Conventionally, a method for displaying a dynamic three-dimensional image utilizes physiological characteristics of human eyes and brain. In this conventional method, usually one or more specially designed two-dimensional images are projected so that the brain considers them to be three-dimensional images, and an observer observes the images. One specific example of this method is a stereoscopic movie. In a stereoscopic movie, each eye of the two eyes receives a slightly different image, and an impression is formed as if viewing a three-dimensional image by the stereoscopic effect.

Usually, the two images are projected simultaneously on the same screen, but the images are adjusted so that they are different in polarity or color, and each observer's eye is configured so that only the correct image enters each. I have.

[Problems to be Solved by the Invention] However, in most of these conventional methods, the observer sees a three-dimensional image only depending on the impression of the observer, and the action of the observer's brain and each eye. This is only due to the impression of the combination of the three-dimensional images seen.

In order to form a pseudo three-dimensional image having the characteristics of a true three-dimensional image, it is necessary that the pseudo three-dimensional image has parallax. Does not have a parallax effect at all, or can only form parallax from one direction, and cannot form a satisfactory three-dimensional image having parallax for observation from all directions. Was.

In addition to this, there is a method for displaying a three-dimensional image using holography.

In holography, Fresnel diffraction of reconstructed light on a fine grating forms a light wave, and the phase distribution of the light wave is the same as the phase distribution of light coming from the object on which the hologram was created.

In this case, the hologram functions as a spatial phase modulator, and the phase modulation applied to the reproduction light beam is determined by the relative position of the grating, that is, the diffraction line of the hologram.

However, in order to obtain a realistic reproduction image, the hologram must have many diffraction lines, and therefore, the resolution of the hologram on which the diffraction lines are written must be extremely high. However, the data to be written on this hologram is extremely enormous, and the required relational data is unrealistically large.

The present invention has been made in view of the above circumstances, and can form a dynamic three-dimensional image having complete parallax, and can reduce the amount of data necessary for forming a dynamic three-dimensional image. It is an object of the present invention to provide a method for displaying a dynamic three-dimensional image that can be reduced.

[Means for Solving the Problems] In response to this object, a dynamic three-dimensional image display method according to the present invention provides a method for displaying a spatial phase distribution of an input light beam from a target to be image-displayed. The input light flux whose spatial phase distribution is known in advance is passed through a spatial phase modulator that converts the spatial phase distribution into a Fresnel-transformed spatial phase distribution according to an electric signal forming an image sequence, and the output light of the spatial phase modulator is observed. It is characterized by having such a configuration.

[Operation] The input light beam passes through the spatial light modulator. Therefore, the phase distribution of the input light beam is converted into the phase distribution of Fresnel diffracted light of light coming from the object to be displayed. This converted output light is similar or identical to the light beam coming from the object.
The spatial phase modulator is controlled by an electric signal such as a video signal to form a sequence of images, so that the observer of the output light sees a complete dynamic three-dimensional image of the object with a parallax effect. Can be.

[Embodiment] Hereinafter, details of the present invention will be described with reference to the drawings showing one embodiment.

In FIG. 1, reference numeral 1 denotes a dynamic three-dimensional image display device used when implementing the dynamic three-dimensional image display method of the present invention. The dynamic three-dimensional image display device 1 includes a laser light source L _S , lenses L ₁ , L ₂ , L ₃ , L ₄ , L ₅ , L ₆ , a mirror M, a beam splitter B, a spatial phase modulator SPL, and a screen. An output plane OP and a control device C are provided. As a laser light source L _s
A light source that emits a spatially coherent laser, such as a HeNe laser light source, is used.

Spatial phase modulator SPL is used is placed in the optical path of the light beam from the laser light source L _S is the modulation of the target to modulate the spatial phase distribution of the light. This spatial phase modulator SP
L is composed of a liquid crystal layer 4 (6 μm thick) sandwiched between two glass plates 2 and 3, as shown in FIGS. These glass plates 2 and 3 are provided with electrodes 5 and 6, respectively. The electrode 6 of one glass plate 3 is composed of small electrodes, and the voltage of each small electrode is individually variable. As shown in FIG. 3, many of the small electrodes 6 are densely arranged in a matrix, and an electric field can be individually applied by the operation electrode drive circuit 7 and the signal electrode drive circuit 8. These small electrodes 6 are placed in 160 × 120 pixels arranged in a rectangle,
Each electronic circuit (scanning electrode driving circuit 7 and signal electrode driving circuit 8) is provided so that the electric field distribution across the liquid crystal layer 4 can be modulated according to the control device C or an external video signal. The inner surfaces of the glass plates 2 and 3 are treated so as to be in a nematic mode in which the glass plates 2 and 3 are twisted by a twist of 0 to 360 °. The alignment of the molecules on the surfaces of the glass plates 2, 3 is shown in FIG.

FIG. 4 is an explanatory view showing the orientation state of polarization of incident light due to liquid crystal molecules in the liquid crystal layer 4.

In the figure, 21 indicates the direction of the orientation of the liquid crystal molecules on the front surface of the liquid crystal layer 4.

Reference numeral 22 denotes a method of aligning liquid crystal molecules on the rear surface of the liquid crystal layer 4.

Reference numeral 23 indicates the direction of the orientation of the electric field vector of the light incident from the front surface of the liquid crystal layer 4.

Numeral 24 indicates the direction of the orientation of the electric field vector of the light emitted from the rear surface of the liquid crystal layer 4 (the electric field emitted through the liquid crystal layer 4 is set to a threshold value).

The luminous flux from the laser light source L _S is expanded by the lenses L ₁ and L ₂ ,
Then, through the beam splitter B, the spatial phase modulator
Reach SPL. In the case of this embodiment, the spatial phase modulator S
As described above, the PL sandwiches the twisted nematic liquid crystal between two glass plates and has a transparent conductive pixel electrode provided thereon. These electrodes form an electric field across the liquid crystal layer such that the orientation of the liquid crystal layer is modified in response to control and video signals from a computer. This forms a distribution of inclination with respect to the plane of the liquid crystal layer, and causes a spatial change in the refractive index by a control signal or a video signal. Therefore, the spatial phase distribution of the light passing through the liquid crystal is modified by this refractive index distribution. The material properties and the thickness of the liquid crystal layer of the spatial light modulator SPL are selected such that the phase can be changed by at least 2π when light passes through the spatial light modulator SPL twice.

Light emanating from the spatial phase modulator SPL is collected by the afocal imaging system 9. The afocal image system 9 includes lenses L ₃ and L ₄ and mirrors the spatial phase modulator SPL.
To form an image on the plane of the M _1. Mirror M ₁ is reflected incident light passed through a spatial phase modulator SPL from the opposite side through the afocal image system 9. The optical system including the lenses L ₃ and L ₄ and the mirror M ₁ forms an image of the spatial light modulator SPL by reflected light, and when the image enters the spatial light modulator SPL again, the pixels of the image are It is adjusted to match the pixel of the air conditioner phase modulator SPL.

The light immediately after passing through the spatial phase modulator reflection image and a spatial phase modulator SPL by the mirror M ₁ of SPL 1 time phase distribution is the same. The light having this phase distribution again passes through the spatial light modulator SPL from the opposite side as described above. As a result, the spatial phase modulation of the light is doubled. The spatial phase distribution of the light that has undergone the double spatial phase modulation is exactly the same as that of the object to be displayed if the object to be displayed is illuminated with coherent light having the same wavelength as the light. The spatial phase modulator SPL is adjusted by a control signal from the controller C or an external video signal so as to have the same spatial phase distribution of the incoming light.

Therefore, the light that has finally exited (after two passes) from the spatial phase modulation layer SPL has the same spatial phase as the light that came from the object,
An observer who observes this light will see a three-dimensional image of the object having parallax.

The light that has finally exited the spatial light modulator SPL is changed in direction by the beam splitter B, and the lenses L ₅ , L
_Go to ₆ .

The lenses L ₅ and L ₆ form the plane of the spatial light modulator SPL on the output plane OP of the optical system 11. By using this optical system 11, the spatial phase distribution on the output plane OP of the optical system 11 can completely match the spatial phase distribution immediately after the light has passed through the spatial phase modulator SPL twice, In addition, it becomes possible to approach the wavefront of the light passing through the spatial light modulator SPL.

In the case of this embodiment, the spatial phase intestinal device SPL uses a nematic liquid crystal. The polarity of light entering the spatial light modulator SPL from the laser light source L _S is adjusted so as to match the direction of the liquid crystal just before the beam splitter B.

This is effective in minimizing the birefringence effect in the liquid crystal layer and making the polarization state of the light that has passed twice through the spatial light modulator SPL equal to that of the laser input light. Therefore, in this case, the polarization of the output light caused by the change in the tilt of the molecules of the liquid crystal layer is minimized.

[Effects of the Invention] According to the present invention, instead of utilizing the characteristics of physiological combinations in the brain from the human eye, it is possible to form a light wave very similar to the light wave coming from the target object itself, and 3D images can be displayed.

In the present invention, the spatial phase distribution of the reproduced light beam is corrected by the spatial phase adjuster instead of utilizing the diffraction by the hologram, so that the number of pixels required by the spatial phase modulator is equal to the number of pixels of the image to be reproduced. Less than the number of pixels. Therefore, the amount of data required for forming a dynamic three-dimensional image can be significantly reduced.

Materials such as liquid crystals used in LCD televisions and deformable gels used in Eidophors can be used as spatial phase modulators, which pass through the video signal in accordance with it. The spatial phase distribution of the luminous flux can be modified.

In the dynamic three-dimensional image display device according to the present invention, a spatially coherent light flux whose phase distribution is known in advance is passed through a spatial phase modulator, and the phase distribution of this light flux is converted to Fresnel diffracted light of light coming from an object. Convert to phase distribution. Therefore, the output light from the spatial light modulator SPL is very similar or identical to the light coming from the object, and the observer can observe a complete three-dimensional image of the object with a parallax effect.
In particular, when the spatial phase distribution is modulated by the spatial phase modulator SPL at a video rate, a sequence of three-dimensional images can be formed, and the observer can observe a dynamic three-dimensional image. Furthermore, if a color filter having pixels is used in combination with the spatial phase modulator, and
Simultaneously irradiating coherent light beams of different colors adapted to the filters with those colors enables display of a dynamic three-dimensional color image.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram of a configuration of a dynamic three-dimensional image display device, FIG. 2 is a schematic cross-sectional diagram of a spatial light modulator, FIG. 3 is a schematic plan view of a spatial light modulator, and FIG. FIG. 3 is an explanatory diagram showing polarization of incident light incident on a phase modulation device and alignment of liquid crystal molecules. DESCRIPTION OF SYMBOLS 1 ... Dynamic three-dimensional image display device 2,3 ... Glass plate, 4 ... Liquid crystal device, 5 ... Electrode, 6 ... Small electrode, 7 ... Scan electrode drive circuit, 8 ... Signal electrode drive Circuit, 9 afocal image system, 11 optical system, L _s laser light source, L ₁ , L ₂ , L ₃ , L ₄ , L ₅ , L ₆ … lens, B… beam splitter, SPL: Spatial phase modulator, OP: Output plane, C: Control device, 21, 22, 23, 25 ... Orientation direction

 ──────────────────────────────────────────────────続 き Continuation of front page (72) Inventor Naotake Oyama 1-2-2 Namiki, Tsukuba, Ibaraki Pref. Machinery Research Laboratory, Institute of Industrial Science and Technology (56) References JP-A-58-68780 (JP, A) 6302 (WO, A1) APPLIED OPTICS. Vol. 5 No. 6 (1966) 967-969

Claims (3)

(57) [Claims] 1. A spatial phase modulator which converts a spatial phase distribution of an input light beam into a spatial phase distribution obtained by subjecting a spatial phase distribution of a light beam from an object to be image-displayed to a Fresnel-transformed spatial phase distribution in accordance with an electric signal forming an image sequence. A method for displaying a dynamic three-dimensional image, wherein the input light beam whose spatial phase distribution is known in advance is made to pass and the output light of the spatial phase modulation device is observed. 2. The method of claim 1, wherein the electrical signals forming the sequence of images are video signals. 3. The dynamic three-dimensional image according to claim 1, wherein a color filter is used together with said spatial phase modulator, and said input light beam is constituted by a plurality of light beams having different wavelengths. Display method