WO1995016340A2 - Stereogram - Google Patents

Description

 Description 3D imaging Technical field

 The present invention relates to a field of a three-dimensional image processing apparatus or a three-dimensional image holding device which requires a three-dimensional image, a three-dimensional photograph, a three-dimensional printing, a three-dimensional display, a three-dimensional recording, a three-dimensional memory, a three-dimensional reproduction, a three-dimensional processing, and a three-dimensional output. Planar image · Planar photograph · Planar printing · Planar display-Planar recording · Planar storage · Planar reproduction · Planar processing · Planar image processing equipment that requires planar output or used in both fields of planar image holding material Yes. Both fields are capable of 3D image processing and 2D image processing.

 Specific examples include eyeglasses, telescopes, microscopes, professional cameras, cinema equipment, movie facilities, monitors, home televisions, medical televisions, satellite broadcasts, teletexts, fax broadcasts, and data. Broadcasting, captain system broadcasting, personal computer communication network, television game system, videophone, home information system, commercial display, display device of various measuring devices, time display device, home or commercial use Photos, books, blueprints, movie software, signboards, neon signs, signboards, three-dimensional geometry, three-dimensional chemistry, bronze images, three-dimensional sample production, other three-dimensional image processing devices, other three-dimensional image processing devices, and Related to other stereoscopic image holders. Background art

Conventional stereoscopic image processing movie-related equipment, stereoscopic image processing TV-related equipment, stereoscopic image processing photograph-related equipment, stereoscopic image processing eyeglass-related equipment, stereoscopic image processing printing-related equipment, stereoscopic image holding photo-related equipment, stereoscopic image processing storage Related equipment, Other three-dimensional image processing related equipment, Three-dimensional processing related equipment, and other three-dimensional image retention ?

The object (however, the above-mentioned each dragon reaming device and the above-mentioned leaping reams are collectively referred to as a three-dimensional image dragon reams hereinafter) are used when observing the target three-dimensional object with the left and right eyes. The method of binocular parallax (mostly based on the above method), the method of hologram by the interference of the wavefront of the light obtained from the target three-dimensional object, and the method by which a two-dimensional image can be stereoscopically viewed. Therefore, the three-dimensional effect is given to the observer by the Pulfrich effect, which is the principle of the port difference method, and by the varifocal mirror method using a vibrating mirror.

 According to binocular disparity, the book “Three-dimensional image engineering” by Takataka Ohkoshi, “Light from a point on the surface of the object being watched forms an image at the center of the retina (center ¾). Light from other points does not form an image at the <corresponding position>, and the binocular image appears shifted. "This left and right shift on the retina creates a stereoscopic effect. According to the dictionary “Kojien” published by Shinmura, “holography” refers to “a laser beam is applied to an object, and the interference pattern between the light obtained from the object and the original light is photographed and recorded on a photosensitive plate. This is a method of three-dimensionally reproducing an image of an object by illuminating it with similar light.This method uses all the factors that create a three-dimensional effect, such as merging, binocular parallax, focusing, and monocular parallax. A satisfactory 3D image is obtained.

 In addition, the Pulfrich effect means that the human eye changes the image transmission speed depending on the amount of light, so when wearing sunglasses at the port only on the left eye, there is a difference in the transmission speed from the left and right eyes to the brain. An image that is born and moves to the left and right becomes an image that is shifted to the left and right, similar to binocular parallax, creating a stereoscopic effect.

 In the vari-focal mirror method, a film-like reflecting mirror is vibrated in synchronization with an image signal displayed on a television screen, and a three-dimensional effect is generated from a vibration image reflected by the mirror.

Therefore, the industrial technology of a stereoscopic image-related object (see the above proviso) is a method of binocular parallax when a stereoscopic object is viewed by the left and right eyes of an observer, and the holographic method. And how to provide the three-dimensional object obtained by the varifocal mirror method using a vibrating mirror in a convenient and high quality manner for the observer Have been working hard.

 However, in a stereoscopic image-related object, the binocular parallax method based on the shift of the left and right images of the stereoscopic object captured from the left and right eyes, and the holographic method of the light wave front interference fringe of the stereoscopic object have a large premise. First, a target three-dimensional object is required. The Alfrich effect method requires a screen that moves only in one direction, and the varifocal mirror method requires a vibrating mirror. Therefore, in both the binocular parallax and holographic methods, which are the mainstreams of stereoscopic images, objects related to planar images are excluded from the subject of stereoscopic image processing, and the vast amount of past, present, and near future 3D image processing related fields have to be newly built from scratch where the fields related to planar image processing have been cut off, so their temporal, spatial, economic, industrial, cultural and industrial losses are enormous. In the method of the Alfrichz effect, images in directions other than the left and right directions are excluded from the target and have little practical effect, and in the varifocal mirror method, the amplitude of the mirror is limited. Therefore, practical effects are not obtained because practical three-dimensional effect cannot be obtained and the principle of stereoscopic vision has not been elucidated. Therefore, a practical three-dimensional effect can be obtained, and the specific problems, mainly the highly practical binocular parallax, which is used in most stereoscopic displays and the principle of stereoscopic vision is clarified, are as follows. Object is not stereoscopically visible.

 Since the mouth and the three-dimensional object are always necessary, the target range is limited to three-dimensional image processing related equipment, which is an unfinished narrow field, so it is completed and spread while keeping the development time and cost low. You need to go.

 C. Two cameras for left and right eyes are needed for film, TV, and photography.

Second, in stereoscopic image processing glasses, natural color images No surface is obtained.

E. For current television broadcasting, it is necessary to add broadcasting equipment.

In the current TV broadcast, it is necessary to secure transmission and reception of two channels for left eye and right eye.

In the current television broadcasting, compatibility between the current television and the stereoscopic image processing television is required.

A stereoscopic image processing TV video desk is required.

Requiring dedicated software for stereoscopic image processing television.

(3) On stereoscopic image processing televisions receiving current TV broadcasts (30 frames per second), time-division display in the left and right directions on each of the left and right LCD glasses with shutter and laminated EL element screen with left and right optical elements ( In a device that halves to 15 frames for 1 second due to the left and right split display, the flicker of the image is noticeable, and the spatial resolution is reduced by half with the lenticular lens plate by expanding the image horizontally. However, in the varifocal mirror method, the image is blurred due to the amplitude, so it is necessary to obtain the same level of image beauty as the current television.

In a stereoscopic image processing movie, a stereoscopic image processing television, and a stereoscopic image processing photograph in a stereoscopic view with naked eyes, a lenticular lens plate, a left and right optical element stacked layer EL device screen that performs time-division display in left and right different directions in When the observer moves his or her head to the left or right, extreme discontinuities in the image occur, and the range of the field of view is narrowed, so it is necessary to widen the range.

ヲ In stereoscopic image processing movies and stereoscopic image processing televisions, when viewing stereoscopically for a long time, eyestrain may occur in 30 minutes, so it is necessary to reduce the fatigue. .

ヮ It is necessary to be able to select a stereoscopic effect according to the image software (action video, news video, landscape video). With the force and pull-flitz effect method, you can stereoscopically view only moving images in one direction. In the binocular parallax method, the stereoscopic effect is obtained only by the binocular parallax, and in the holographic method, experimental stereoscopic vision in a limited horizontal direction is obtained due to the large amount of information. The stereoscopic effect can be adjusted to enhance stereoscopic images (landscapes / moving pictures) in the horizontal and diagonal directions from top to bottom. Practical fusion, binocular parallax, parfocal adjustment, monocular movement A stereoscopic image processing method capable of parallax is required. In the printed matter holding stereoscopic images (side-by-side image parallel, side-by-side image fusion, 3D stereogram, random pattern), only one of the viewpoint parallel method and viewpoint intersection method can be used for stereoscopic viewing, and the stereoscopic effect is further enhanced. It is also desirable.

 The present invention has been made in view of the above circumstances, and the object thereof is to enable the industrial technology to enter the three-dimensional image processing field without cutting off the two-dimensional image processing field. Time, space, economy by providing `` methods and principles for manufacturing 3D image holders, 3D image processing devices, and 3D image processing devices '' from 2D image holders and 2D image processing devices. The purpose is to eliminate the vague loss of cultural heritage. BRIEF DESCRIPTION OF THE FIGURES

Fig. 1 shows the binocular fusion of the present invention 'Bimorphic fusion' ■ Binocular fusion (Fig. 1A), binocular fusion * binocular fusion * both-time fusion (Fig. 1B), binocular fusion ( Figure 1C), Bilateral fusion (Figure 1E), Biclinic fusion (Figure 1G), Biclinic fusion (Figure 1F, 1H, 1I), and Bilateral fusion (1HIJK) (However, each method is a coined word for explanation, and will be described later, and will be omitted below.) 3D image production, 3D image processing device production, and 3D image-related 3D image processing devices Fig. 2 is an explanatory diagram showing the configuration of the principle of Fig. 1 and the configuration in which the left and right or front and rear images are exchanged (Fig. 1D). Fig. 2 shows the two-air fusion (Fig. T), both space-time fusion (Fig. 2A ~ X), double-tilt line fusion (Fig. 2W), and double-tilt point fusion (however, each method is also a coined word) FIG. 3 is a diagram showing the configuration of the two-position fusion, the single fusion, the binocular fusion, the binocular fusion, and the binocular fusion. Fig. 4 is an explanatory diagram showing an experimental configuration when stereoscopic image production by using a teletext receiver, a color television, a video recorder, a video taper, and a video camera is used. Image production using stereoscopic image processing glasses, or using cylindrical lens and ge filter Fig. 5 is an explanatory diagram showing the configuration of the experiment when it was realized.Fig. 5 shows an experiment when stereoscopic image production by the binocular fusion method was realized and observed using photographs or printed materials and a lenticular lens plate. FIG. 6 is an explanatory diagram showing a configuration, and FIG. 6 is an explanatory diagram showing a configuration of one method of manufacturing a processing portion of the image stereoscopic processing device by each of the two-time fusion or the two-time tilt fusion method. Are binocular fusion (Fig. 7A), binocular fusion (Fig. 7A), binocular fusion (Fig. 7 BC), binocular fusion (Fig. 7 BC), binocular fusion (Fig. One example of manufacturing each image stereoscopic eyeglass by each method of binocular oblique fusion (Fig. 7BC), and single-sided / bi-tilt line / bi-tilt point fusion (Fig. 7B). 8A and 8B show two-time space-time fusion, two-time space-eye fusion, and two-time space-tilt fusion in observation from only one direction. FIG. 9 is an explanatory diagram of one configuration example of a display unit of an image stereoscopic processing device using each method of binocular spatiotemporal fusion. FIG. 9 shows a conventional stereoscopic method using binocular parallax (FIG. 9A). FIG. 9B is an explanatory diagram showing the configuration when the image is switched left and right (FIG. 9B). Disclosure of the invention

The present invention provides a flat object, a three-dimensional object, and a drawing From the image information of the image obtained from the projected surface image, the image information of the image shape information of the image when it has the same shape as the varifocal mirror, two or more monocular shooting points, two or more monocular viewpoints, and 2 When the binocular parallax image of each of the assumed monocular viewpoints is projected over the entire time corresponding to each eye of the observer, the image information of the phase space information of the observation point of the image and Hue information, saturation information, luminance information, color and image aberration information, image shape information, image image existence information, decorrelated phase space between the display surface image and the display observation image Each image information is divided into warm color and cool color in hue information, port color and light color in saturation information, and light and dark in luminance information. Each fusion between the two is called a two-color fusion.) In the soft-focus system and the hard-focus system, in the image shape image information of the image, part, multiple parts, or all of the image shape is enlarged, reduced, vertically or horizontally compressed, or By combining each of the expanded image information or each of the full-size image information, the large image system and the small image system can be combined. In the image existence information of the surface image, one part of the image or multiple parts exist in the image system and the non-image system (hereinafter, referred to as single existence fusion), and the display image and the display observation image In the uncorrelated phase space information, the same system and two or more multiple systems (hereinafter referred to as “floor fusion”), left system and right system, forward system and rear system, or upper system and lower system, each with one or more systems (Hereinafter referred to as double-tilt fusion, double-tilt fusion, double-tilt line fusion, and double-tilt point fusion) In the comparison of information between the systems, one heterogeneous difference holding image information having one heterogeneous difference information is used alone or in combination with each other with one other heterogeneous difference holding image information. Image information display, same recording, same storage, same recording / reproducing as left-eye image processing information and right-eye image processing information or as front image processing information and rear image processing information , An image processing device capable of performing at least one of image processing of the same storage and reproduction, the same reproduction, the same processing, and / or the same output, or each image information of an image carrier capable of performing the function Image information is displayed from the display unit in the processing unit or from the display unit in each image information processing unit that has transparency (hereinafter, both color fusion or both shape fusion between the left and right monoculars). A method of fusing by comparison is referred to as a binocular fusion method), or a display unit in each of the image information processing units has a phase in a spatial position (hereinafter, referred to as a binocular fusion), and a phase space difference Image information is displayed from each of the display sections having a mark (hereinafter, a method in which binocular fusion is added to binocular fusion is referred to as a binocular fusion method).

 Alternatively, the image processing information for the left eye and the right eye is provided with a time difference within a time period in which the image fusion effect by the afterimage is effective in each of the image processing information, or the image processing information for the front and the rear is used. Are alternately replaced with each other, and time-division display is performed from each of the display units of the image processing device or the image holding material, or from the display unit of each of the transparent and transparent image processing units (hereinafter, referred to as “display unit”). A method of displaying the two-color fusion or the two-way fusion in a time-sharing manner is referred to as a two-time fusion method.) Or, the display unit in each of the image information processing units has a spatial position phase (two-space fusion). Image information is displayed from each of the display sections having a phase space difference (hereinafter, a method in which the spatiotemporal fusion is added to the spatiotemporal fusion is referred to as the spatiotemporal fusion).

 Alternatively, the rooster image processing information is displayed at one time on the image information display unit, and the binocular fusion is performed.At the next time within the image afterimage effective time, a difference from the previous time is different. The image processing information is displayed on the display unit in the form of image information and displayed in a time-division manner so as to perform a binocular fusion different from the above (hereinafter, referred to as a binocular fusion). Each of the display sections having the phase space difference is time-divisionally displayed from the display section so as to perform the fusion (hereinafter, referred to as both-time and space-eye fusion).

Alternatively, the image shape information of the image in the case of forming the same shape as the varifocal mirror and the observation point phase space information of the image in the case of performing the binocular parallax method over all the time points are different in the same kind of information. For each image information with system differences, One or more of the various kinds of allogeneic heterogeneous difference holding image information are added to each of the image information, and the image information is displayed so as to produce each of the above-mentioned fusions. The method that includes the fusion method is distinguished by “visual” and is distinguished>.

 Of these methods, both the binocular fusion method and the binocular fusion method (described in the above “I”, hereinafter, elimination is omitted) are based on perspective fusion based on each difference in the anterior-posterior direction and vertical and vertical directions on the retina. Therefore, the operation resulting from the configuration by each of the fusion methods will be described together with reference to the drawings.

 In Fig. 1A (binocular fusion) and Fig. 1B (binocular fusion), the observer 1 looks at the image information display section 61 and sees the binocular fusion method (Fig. 1A). In the right-eye / front image display unit 6 and the two-time fusion method (Fig. 1B), the image-related objects are shared by each eye. Projected onto the retina of the right eye 3 when using the eye fusion method, and onto both the retinas of both eyes 2 and 3 when using the bilateral fusion method, the warm color system 13 is used for the hue information, and the saturation information is used for the saturation information. Is the dark system 15, the brightness information is the bright system 17, the aberration information is the hard focus system 19, and the image presence information is the imaged system 23, and the image According to the image shape information of, the large image system 21 is felt to be ahead of the fusion image 9.

In the same manner as described above, the left-eye image display unit 5 for the left eye or the common image display unit 5 for both eyes at the next time is projected, and the left-eye image display unit 5 using the binocular fusion method (FIG. 1A) is projected. On the two retinas of both eyes 2 and 3 at the next time point (Fig. 1B Loha) on the retina of Fig. 2 and at the next time point using the two-time fusion method, the cool color system 14 is shown in the hue information, and the saturation information is shown in the saturation information. , The light color system 16, the luminance information, the dark system 18, the aberration information, the soft focus system 20, the image existence information, the non-image system 24, and the image of the image In the shape information, the small image system 22 appears to be behind the fusion image 9. In Fig. 1A and Fig. 1B, the left, right, front, and back and front and back and front and back and front and back with the afterimage fusion effect. Differences in image information of 13 and 14; 15 and 16; 17 and 18; 19 and 20; 21 and 22; 23 and 24; At the pivot 4, the processing of processing the left, right, or front and back as one image causes the fusion of the left, right, front and back two image information 7 and 8, and the hue information and saturation Degree information · Luminance information · Aberration information · Image existence information · Image image shape information 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24 intermediate information is newly created, and one image 9 is recognized in the middle by the intermediate information.

 Based on the intermediate image 9 of the visual center, the forward sense image information 8 and the backward sense image information 7 produce a relative three-dimensional sense 10 of the forward sense 11 and the backward sense 12, respectively. You can see it.

 In addition, Fig. 1 EF GH IJK explains the two-sided fusion, the two-sided fusion, and the two-sided fusion. In Fig. 1E, two identical images 130 and 13 1 are observed in parallel and the displayed image is displayed. After creating a shift in the phase space between the image and the displayed observation image, when the crying fusion is performed, the fusion image 134 is interposed by the fusion information of the rear-sensing image information 132 and the front-sensing image information 133 as described above. Similarly, it can be created and stereoscopically viewed (figure fusion).

In Fig. 1G, when the display image 140 and the display observation image 144 are tilted, the display observation image 1441 merges the left and right two images 1442 and 1443, and both light images appear. A stereoscopic vision similar to the fusion can be obtained (bilateral fusion). In addition, in the tilted display image 140 of Fig. 1F, the illusion of a display observation image can be seen as if it were ahead. Displaying the back illusion image 144 of the same back illusion as that of the image 145 gives a fused image 146 that can move the focal point in the middle, and enables stereoscopic viewing as described above (bilateral fusion). Become. Contrary to the above, Fig. 1 Table in HIK When the display image 150 is not tilted, the display observation image is displayed with an illusion of tilt due to the illusion of 151, 152 and 154, 155, and the fused images 153 and 15 are displayed. 6 can be obtained, and in Fig. 1 JK, each trapezoidal image is displayed in a time-division manner, a two-sided fusion, or a fusion display such as a binocular fusion. 15 1 and 154, 15 2 and 15 Then, each of the fused images 157 and 158 of a medium-sized square is obtained, and a fused image 159 of the images 157 and 158 (hereinafter, an image between the three-dimensional image layers is particularly referred to as a layer image) is obtained. As a result, stereoscopic vision can be achieved as described above (bilateral fusion).

Next, the operation of the binocular fusion method and the spatio-temporal fusion method of displaying each of the display units with a phase in a spatial position will be described. In FIG. Looking at each of the left and right or front and rear display sections 5 and 6 with a difference pattern (both top and bottom-left right and front and back · front and back · line ■ Each point has a symmetric basic pattern), each fused image Is formed in the virtual image space in the visual center 4 of the observer 1 in a virtual image space in the middle of the display unit (hereinafter, referred to as a virtual sky image). When the observer 1 is in a stereoscopic view, Since the focus adjustment position can be moved and selected on each of the left, right, up, down, front and rear display surfaces 5, 6, and 61 and on the imaginary image surface 9, natural stereoscopic vision can be achieved. Next, a description will be given of a method of merging the space-time and space-eye. In FIG. 2, three display surfaces 16 1, 26 1, and 36 1 are used (the basic patterns are shown in FIGS. 2E to S, W, and X). Each pattern has left and right, up and down, front and back, and lines ■ Each point has a symmetric shape〉, two faces for both binocular fusion, and one face for both space-time fusion When the time-division high-speed cyclic display is performed in 26 1 and 36 1, a secondary fused image 9 C (referred to as a vacant layer surface image) of the fused images 9 A and 9 B is created, and the vacant layer image 9C is a fused image layer that is thicker than the fused image of the planes due to the layer-by-layer fusion of the three-dimensional image layers (9A and 9B). Figure 2 Display with phase difference in Irohanihoto If the number of sections 4 6 1 and 5 6 1 is increased, 3 Then, a fused image 9D (hereinafter, referred to as a virtual image overlay image) obtained by multiply-fusing the fourth order is obtained. Also, the fused images 9C and 9D can be observed from three horizontal directions because of the line symmetry display.

 Next, the two-way line fusion and the double-tilt point fusion will be described. In FIG. 2W, the dual-angle fusion method described in FIG. 1F and FIG. In addition, the display observation fusion image is symmetrically rotated and displayed so that 9A and 9B can be observed by the illusion of 9A and 9B so that the fusion image has the same shape as the display observation fusion image 9C (double tilt line fusion method). It is possible to obtain a fusion rooster image with little blurring (called a vacant standing image). Also, as shown in Fig.2, the display section of the two photos, the display section is increased and the multiple fusion is performed, as shown in the display section 461, 561, and the imaginary layered image in which the tilt fusion is working (hereinafter referred to as the imaginary layered image) In addition, in FIG. 2X, the line symmetry is point-symmetrically displayed as a point symmetrical point (both tilting point fusion method). Images can be obtained.

 The images of the Void layer, the Void layer, the Void layer, and the Void layer are merged Kakuyuan, left-right parallax fusion (working very close to binocular parallax), monocular parallax (the image moves), Equipped with a focus shift (working very close to focus adjustment), similar to a holographic image (capable of blending «, binocular parallax, monocular parallax, and focus adjustment), with few physical constraints (external to the observer's body) The difference is whether the image is displayed on the screen or in the same body), so that it is possible to handle moving images and landscape images, and obtain an ideal image within a practical range.

Next, the methods of binocular fusion and binocular oblique fusion will be explained. At one time, binocular fusion occurs, and at the first time, binocular fusion different from that at one time occurs. However, when both-time fusion occurs at each time point, a fusion image of stereoscopic images can be obtained at the second time point in the two-time fusion, but in this two-hour eye fusion, At the next point, a fusion image of the three-dimensional images (Referred to as a layer image), and the method shown in Fig. 1K is combined with the bi-inclinical fusion (bilateral oblique fusion). A line rotation image is displayed as if it is rotating (hereinafter referred to as both-sided tilting line fusion), or a point-rotated image is displayed as if the center point of the sphere is being rotated at a point (hereafter, both-sided tilting) By performing point fusion, it is possible to obtain a three-dimensional image (hereinafter, referred to as a standing image) that adds a three-dimensional effect to the three-dimensional effect.

In addition, in FIGS. 9A, 9B, and 1C, a stereoscopic image based on the conventional binocular parallax is also displayed on a plane image display section in a conventional planar image-related object alternately at high speed in a time-division manner. The fusion between the virtual image 53 in Fig. 9A and the image 54 in Fig. 9B occurs, and a stable fused image 55 in Fig. 1C is obtained, enabling stereoscopic vision without image skipping with the naked eye. Therefore, each method of binocular parallax can be independently added to each other fusion method. In addition, each method by a combination of two or more can be used. It can be added to each method. In addition, in FIGS. 1A and 1B, the differences between the left, right and front and rear image information are 13 and 14, 15 and 16, 17 and 18, 19 and 20, 21 and 2. By increasing 2, 23 and 24, and the difference 13, 14, 15, 16, 17, 18, 19, 20, 21, 22, 23, 24 If each of these is combined, the depth 10 of the relative stereoscopic effect of the observer 1 will also increase. Similarly, if the difference (symbols omitted) is reduced, and if the above combinations are removed, the depth 10 of the relative stereoscopic effect of the observer 1 is reduced. If the difference (symbol omitted) is set to zero, the three-dimensional effect is eliminated, and the three-dimensional image display surface can be changed to a two-dimensional image display surface. In addition, when using the above-mentioned difference (symbol omitted) and each of the above-mentioned combinations individually or in combination, the ratio between the left and right and the front and rear is changed to increase or decrease, and by removing the combination, The fusion position of the image 9 can be moved to the front and back of the display surface 61, and the sense of front 11 and the sense of back 12 based on the image 9 can be increased or decreased. Various three-dimensional effects corresponding to the foot can be obtained. BEST MODE FOR CARRYING OUT THE INVENTION

 A stereoscopic image processing system using a binocular fusion, binocular fusion, bilateral fusion, single fusion, double tilt fusion, double tilt line fusion, and double tilt point fusion method. Referring to the drawings, a simple experiment in which the present method is applied will be described to demonstrate that an image holder, a stereoscopic image processing device, and an image stereoscopic processing device can be manufactured. In FIG. 3, a commercially available color television monitor, three monitors of the same model and the same inch (hereinafter referred to as monitors A25, B26, and C160), a teletext receiver 29, a video recorder 28A, 28B and 28C, video camera 30 are arranged as shown in Fig.3, monitor A25 receives the current subtitled text broadcast, and monitor B26 displays the subtitle-free broadcast. I do. Video recorders 28 A, 28 B, and 28 C, each time recording on each videotape, and two mirrors at the center, tilted 45 degrees left and right from the horizontal vertical plane right at the center of the video talent 30 (Adjust to a right angle) and align the vertical line of both mirrors with the center line of the video camera. Make the left and right monitors A25 and B26 from mirror 27 the same, and adjust the image size. In the same manner, the image is displayed on the monitor C160, and the left and right images are observed by the parallel method so as to correspond to each eye of the observer.

Next, adjust the hue adjustment knob on the monitor A25 · B26 · Color density adjustment knob 'Brightness / darkness adjustment knob · Image quality adjustment knob · Image adjustment knob to the left and right to obtain the same image on the left and right. Only the subtitles floated to the front and could be viewed stereoscopically. (Single fusion) In the comparison between the monitor A25 and the monitor B26, the difference of each picking unit is created and the fusion observation is performed. Was. Next, a black-and-white photograph is placed on the CRT of monitor A 25, and the black-and-white photograph is placed horizontally or vertically on the brown tube of monitor 26. Stretch each picture, tilt each CRT in multiple directions and observe Was. The ratio at which the three-dimensional effect was reasonably obtained was 100: 167 or 100: 60 in the horizontal direction, and 100: 1: 114, or in the vertical direction. , 100: 88 were obtained as allowable ranges for stereoscopic vision. The high number in the lateral direction is that the human eyes are arranged side by side and the optic nerve crossing part has an image as shown in Fig. Presumed to be. Next, change the screen of monitor A 25 to a blank screen and set monitor B 26 to a black-and-white screen. Monitor A 25 ■ Move B 26 closer to or away from central mirror 27 to obtain the saturation and image. When the perspective fusion images are the same size, when the image on monitor A 25 is larger than the image on monitor B 26, the color of the color is strong and when Black and white was emphasized. The above indicates that the fused image has a width and includes both states of equal left and right and superior and inferior left and right.

 Explaining the experiment in FIG. 1A, it is shown that the imaging position of the fusion image 9 using morphology can be imaged by moving the front and back of the display unit surface 61 according to the left-right ratio of color vision. Therefore, it is shown that the strength of the forward sense 11 and the backward sense 12 based on the fusion image 9 using the morphological sense can be eliminated by combining different sensory functions. This means that in one morphological fusion image, there are countless fusion images of each hue, each saturation, each luminance, and each aberration for each left-right ratio difference (left-right uniformity and left-right superiority) in the front-back direction. And the fact that a fusion image of two or more combinations of the innumerable fusion images can exist, it is possible to provide a stereoscopic effect corresponding to various image software. Is shown.

 Next, the videotare obtained in the experiment using the black-and-white photograph is reproduced by a video recorder 28C and projected on the display surface of a monitor C160, and the image is transmitted by a commercially available still image videophone that transmits a static image by wire. Copy I could observe and stereoscopically view the same videophone 100 km away.

Next, the difference between the image shape information of the left and right images of the binocular fusion method Alternatively, the front and rear images 41 and 42 of the printed matter are alternately arranged, and a pair of left and right ones is used for the stereoscopic image display photographic principle corresponding to one lenticular lens 45. In the experiment of the printed matter or the lenticular lens plate, the observer 1 However, when the head is moved from point A in Fig. 5 to point B in Fig. 5 by moving the head to the left or right, or when the lenticular lens plate or the entire image under the lens is shifted left and right by one image, When the left and right images 4 1 and 4 2 shift from left and right reversal 4 1 to 4 2 and from 4 2 to 4 1, there is momentary dizziness, but extreme image discontinuity due to image skipping occurs. I didn't come.

 In FIG. 9AB, according to the conventional binocular parallax method, the observer 1 moves his neck left and right and moves the left and right images 51 and 52 from the stereoscopic view of the virtual image 53 in FIG. 9A. Left-right reversal · When shifting from Figure 51 for left eye to image 52 for right eye, from image 52 for right eye to image 51 for left eye, and to Figure 9B showing the situation, observer 1 sees a virtual image, Extremely moving and deforming from the virtual image 53 to the virtual image 54, it was not possible to connect the virtual image 53 with the same position and the same shape, and extreme discontinuity of the image occurred.

 Therefore, although the field of view was narrowed, in this fusion method, in Fig. 1D showing the situation where the left and right inversion occurred, the fusion image 9 of the same position and the same shape as Fig. 1A can be connected. However, it can be said that there was no extreme discontinuity of the stereoscopic image, and the visual field range was wider than before.

In FIG. 1 AD, when the observer 1 feels physiological eye fatigue, he or she voluntarily moves his or her neck to the left or right, or a lenticula board. The movement 67 to the forward feeling, which is the function of the left and right eyes, and the movement 68 to the backward feeling, which are the functions of the left and right eyes. The movement 68 to the backward movement and the movement 67 to the forward feeling from the backward movement 67 occur, and in the one-eye work, the work of the eyes in the opposite direction is generated, and as a result, the eyestrain is reduced. Obey With the conventional stereoscopic image display method based on binocular parallax, those who feel tired in about 30 minutes can now maintain for a long time.

 Next, in Fig. 4, a simple image three-dimensional processing eyeglass device 33 applying the stereoscopic image manufacturing method based on the difference in image shape of the images of the binocular fusion method was used. Observing the plane image of the monitor A 25 composed of 2 and 3 4 as shown in Fig. 4, the observer 1 can see the front image stretched left and right and left and right in the left eye 2 and the left eye in the right eye 3 The compressed rear view image was visible and stereoscopic. In addition, when observing other three-dimensional objects, it was possible to observe by increasing the stereoscopic effect by several steps compared to the case of binocular parallax observation with only the naked eye. With conventional stereoscopic glasses using complementary colors, natural colors could not be obtained. Also, it can be said that adding this fusion method to the conventional binocular parallax further enhances the stereoscopic effect.

Next, each method of binocular fusion, binocular fusion, biclinal fusion, both-side fusion, single existence fusion, double-tilt line fusion, and double-tilt point fusion in the display surface and in the virtual image space Among them, an experiment in which a stereoscopic image was manufactured using printed matter due to the difference in hue and luminance (hereinafter referred to as Experiment A) The same experiment in which the image shape in the same method was different (hereinafter referred to as Experiment B) An experiment using two photographs taken at 45 ° left and 45 ° right and 45 ° right from the vertical center line of the same image. (Hereinafter referred to as “Experiment D”) The same image was moved from the vertical center line to the left and right from the horizontal center line of the image by 45 degrees each, and from the point moved by 45 degrees each to the right. In five simple experiments of two photograph experiments (hereinafter referred to as Experiment E), in Experiments A and B, a person with 3 CM Using an object image, on a white paper of 3 CM in length and 6 CM in width, and in Experiment CD and E, two photos of the same person black and white image of the same shape (3 CM in width and 6 CM in width) were processed or Basically, in each experiment, a front rooster image was printed on the center left and a rear human image was printed on the right side, and both the viewpoint parallel method and the viewpoint crossing method were used. Swap the image of left and right and re-mark ¾ Also, 4 5 in Experiment C In addition to the experiments in Experiment E, the center left and right photographic alignment lines were raised or lowered and the inclination angle was 45 degrees from each horizontal plane. The photographs were placed parallel to the horizontal plane and observed and compared at an angle of 45 degrees each left and right, and each top and bottom.

 Experiment A: The basic natural color at the time of the experiment was yellow (hereinafter referred to as Y) 1. Magenta

(Hereinafter referred to as M) — 2, cyan (hereinafter referred to as C) ± 0, and black +2, so the hue is adjusted by adding and subtracting M and C respectively by ± 4, and the luminance is increased and decreased by ± 4 for black and left and right images. And Y—4, M + 2, C—4, and Black—2 are used as the front person image, and similarly, Y—4, M−6, C + 4, and Black + 6 are used for the rear. It was a person image.

 Experiment B: The portrait image was taken as the back person image, and each person image enlarged 1.35 times horizontally, 1.35 times horizontally and 1.10 times vertically was used as the front person image. .

 Experiment C: Bilateral fusion of two left and right photographs placed side by side on a horizontal plane, oblique fusion was performed by observing one photo at an oblique angle of 70 °, and then the binocular colors used in the experiment in Fig. 4. The observer puts on the fusion glasses 33, tilts the left photo down 45 degrees, tilts the right photo up 45 degrees, observes through the glasses 33, and then returns to the original horizontal position, then left Only the front image photograph of the above was lifted over 8 CM, and the observation experiment was performed from just above 35 CM above the horizontal plane.The right photograph was marked with a circle, and the observation was performed. The same observation experiment was performed on a parallax portrait.

Experiment D: Two photographs in which the displayed human image is observed to be 45 ° left and right symmetrically different from each other are rotated by 45 ° each left and right, and the observed human rooster images are matched, and through the glasses 3 3 Further, the right photograph was tilted forward by 30 degrees, the left photograph was tilted backward by 30 degrees, and the same observation was made while moving the whole back and forth. Experiment E _: A 90-degree phase space point symmetric centered on the base photo, in which the displayed human image is observed to be different from left to right and up and down by 45 degrees each in the base photo Each of them was tilted by 45 degrees upward and rotated by 45 degrees each to the center point of the basic photograph so that the display plane image and the observed image coincided. The movement was observed in the same manner as in Experiment D.

Experiments A, B, C, D, and E have vivid natural colors, or a three-dimensional human image of intermediate size emerges on the display surface or in the center of the vacant space, and at an angle of 45 degrees each. Observation from the corner (the stereoscopic projection, the difference between left and right similar to binocular parallax ■ Because the difference between the top and bottom is working) The most natural and high stereoscopic effect is obtained when realizing a vacant rooster image that can also move the focal point In Experiment E, a natural three-dimensional effect appears more prominently. Also, in the imaginary sky image obtained at the same 45-degree tilt angle, when the center part is a valley and a mountain, the sense of spread of both sides is increased. In addition, the difference in the sense of protrusion from the center and the center is obtained, and the fusion image production function and the gazing point and focus function are independently starving, and the three-dimensional recognition is mutually confirmed in conjunction with each other. Understand the respective stereoscopic experiments. Next, in the display unit surface and in the virtual image space within the observer's visual center, the spatiotemporal fusion, the spatiotemporal fusion, the spatiotemporal fusion, the spatiotemporal fusion, the spatiotemporal fusion, the spatiotemporal fusion, Photographs by tilt fusion, both-time and space-eye visual fusion, both-time and space-eye inclination circuit fusion, both-time and space-eye inclination circuit fusion, both-time and space-eye inclination point fusion, and both-time and space-time eye inclination fusion A simple experiment using printed matter to produce a three-dimensional rooster image, a vacant rooster image, a vacant layer image, a vacant layer image, a vacant layer image, and a vacant layer image is described as a basic black and white image. Using a portrait photo (3 CM in height, 6 CM in width), the basic photo with an image-shaped blur added is K, the photo is 1.3 times the same, and KY is 1.3 times the photo, and 1.3 is the same. 5 times '' Vertically 1.10 times photos are called KYT, and each photo is a 3 CM wide 6 CM photo, and the experiments F, G, H, I are performed. In Experiment I, image processing was performed on the photo used in Experiment D, and the image was processed using axisymmetric rotation. Similarly, image processing was performed on the photo used in Experiment E. Each experiment was performed using 0 degree point symmetric rotation.

Experiment F: On the right edge of a white rectangular paper (3 cm long and 20 cm wide), print the photos K and KY one by one, and make a total of 30 sheets of 15 sheets each, and alternate each one of them. A total of 30 left-bound books were piled up and bundled together, moth was painted on the right edge to make them slippery, and the books were slid up with thumbs and turned up while sliding.

Experiment G: Two black disks A ■ ■ At the left end of disk A of B (each radius 50 CM), stretch the picture and KY up and down toward the center point, and overlay disk B on disk A. Open the small window (3 cm long and 5 cm wide) where you can see Photo 1, attach the stop metal and stop bar so that each photo K and KY temporarily stops at the small window, and reciprocate the disk A to the left and right Rotated and observed.

Experiment H: The photo ,, KY was placed on the outer leg of a cylindrical cylinder (radius 50 CM), side by side left and right, and the cylinder was covered with a black outer cylinder (radius 51 CM). Opening the window, attaching the stop fittings and the stop rod so that the photographs K and KY temporarily stop at the small window, and reciprocating the inner measuring tube left and right for observation experiments.

Experiment I: 30 cm long, 5 mm diameter wooden square bar, 3 cm long 1 cm diameter metal center bar attached to the center, 3 cm long, 5 cm wide, 5 cm wide Put one picture K and KY on the surface of each of the two boards, and fix the 1 MM square bar between the back sides of each board so that each picture can be seen from the outside. 0 ° 90 ° 1 20 ° 1 5 0 ° 1 80 ° High-speed / low-speed Reverse, and the same photographic plate (K, KY) as the photographic plate (, KY) as shown in Fig. 2 U Observation experiments were similarly performed on the cruciform rotating plate mounted at a slight right angle at the center in the same manner, and a photograph obtained by adding the difference in image shape at the same ratio as the photographs K and KY to the photograph used in Experiment D above (Hereinafter, DK, D

KY), and perform the same experiment as above. Observed from three points, and as shown in Fig. 2V, a photograph obtained by adding the image shape difference of the image at the same ratio as that of the photograph used in Experiment E (hereinafter referred to as EK and EKY) at 90 degrees The center point was fixed at one point of the 1MM metal bar so as to be symmetrical, rotated 90 degrees reciprocally, and observed from three directions of 20 degrees left and right and the center.

In Experiments F, G, H and I, the brightness difference fusion experiment in which each photo 写真, DK or ΚΥ has a light gray finish and each photo Κ, DK or Ε has a light natural color finish And photos ΚΥ, D KY or Ε Κ Υ 潙 ぃ 潙 ぃ 潙 ぃ 潙 ぃ 潙 ぃ と と と と と 各 各 と 該 各 該 各 各 各 各 該 各 各 各 該 各 該In addition, each color hue difference experiment in which the photograph ,, DKY, or Ε Κ 薄 was applied with a light red-yellowish color finish, and three kinds of experiments in which the photograph ΥΤ was added to the experiment using the photograph Κ A photographic experiment and each experiment using the combination of the three types were performed, and a photograph taken by the binocular parallax method was similarly experimented. Further, all the experiments were performed for the binocular fusion used in the experiment. Observed through glasses 33. In each experiment, stereoscopic vision was obtained like a phantom light machine that vibrates finely.

Further, in Experiment F, each fusion was difficult to occur at 15 mm for 1 second, and a sufficient three-dimensional fusion image began to be obtained from about 30 frames or more for 1 second. In the case of the combination of → 類 → ΚΥΤ → Κ Υ—Κ →, the most natural and most stereoscopic image was obtained. However, although it was not about both eyes, stereoscopic vision with a clear stereoscopic effect was obtained, and experiments on the use of the two-way space-time tilting line fusion method and the two-way space-time tilting point fusion method using stereoscopic glasses 3 I Can be observed as if there is one three-dimensional planar display image from many horizontal directions, and since there is little blurring of the image, there is a translucent copper figure human figure in the space The most natural thickness that allows the illusion and focus shift (the focus can be shifted to each surface in each imaginary rooster image and each of the front and back image display photo surfaces). An ideal three-dimensional image with good quality was obtained. Based on the above, we devised bilateral fusion, bilateral fusion, and binocular fusion from the source to the plane image information and the stereoscopic image information created by the conventional binocular parallax method. A method for creating a stereoscopic image and the same processing device, and displaying the stereoscopic image on the planar information processing device side by devising two-time fusion, binocular fusion, bilateral fusion, and binocular fusion. In the case of a movie, if the movie film that is the information source is 24 frames per second, one film is processed by image processing for the front rooster image film and the rear image film. If the film is projected at a double speed with the existing projector, or it is replaced with two films Divided into two separate projectors, and two projectors at the same speed When the image is projected onto a screen that uses a sheet (in the above case, an imaginary image can be obtained at the first time), the flicker caused by the naked eye in a wide field of view ■ Color and spatial resolution decrease (enlarged in the forward image) Although the spatial and spatial resolution is reduced, the image is compressed using the rear image, and the same resolution is increased. When the image is merged, the height is lost.) In the image processing section of the image stereoscopic processing apparatus, the light 71 that has passed through the odd-numbered projection film is used for the front of the cylindrical lens convex 7 2 and concave 7 3. The light 75 transmitted through the next even-numbered movie film at the next point in time is converted into a video image and projected on the screen 74, and the mirror 7 8 Is reflected by the convex mirror, and is reflected by the convex mirror. The horizontal image is processed into a compressed image for the rear side, corrected by the refractive index adjusting glass 80 vertically in the same bending direction as the image for the front side, reflected on the mirror 77, and then projected on the screen 74. The shutter with mirror 76 can be replaced with a half mirror to adjust the image optical path of even and odd frames by interlocking two other liquid crystal shutters. In addition, three outgoing light ports can be used to support three-sided or one-sided screens (image projection compatible with double-tilt fusion, double-sided line fusion, and double-tilt point fusion is also possible). The By attaching the image stereoscopic processing device to the existing movie projection device, it is possible to see a flicker with the naked eye in a wide field of view and a stereoscopic image rooster without deterioration in color and spatial resolution. At a broadcasting station, an image of light captured by a television camera is converted into an electric image by an image pickup tube, and horizontal scanning obtained by scanning with an electron beam is used to scan a rooster image for the front and a rooster image for the rear. A scanning electric signal is added or subtracted, and a synchronization signal and a blanking signal of the front and rear image-processed electric signals are added to each other, amplified and transmitted by a transmitter, or before a television camera. When a stereoscopic image processing device with the same configuration as the optical device in Fig. 6 is installed and images are transmitted in a normal manner and transmitted, the flicker, color and spatial resolution of the existing flat-screen TV that has received the radio waves with the naked eye in a wide field of view Three-dimensional rooster without drop With the ingenuity of the receiving image processing device side, the horizontal scanning of the electron beam is extended and the compression direction is repeatedly activated to display the forward and backward images at different times. A circuit that separates and adjusts the horizontal synchronization signal and vertical synchronization signal from the synchronization signal, and two horizontal scans per frame correspond to the front horizontal frame scan and the rear horizontal scan scan, for a total of two frames By adding a horizontal scanning signal converter that repeats horizontal scanning in units of four times as one operation and a signal converter that performs synchronization processing that synchronizes with the scanning frequency, flicker and color with the naked eye in a wide field of view And the stereoscopic image without spatial resolution degradation can be seen, and the display of characters, numbers, symbols-codes, and patterns on the display unit of the processing device display characters, display numbers, display symbols, display codes, display patterns (however, In this description, " The range of “images” includes objects that can be seen, letters, numbers, symbols, signs, patterns, etc., to cover everything. However, some of them are projected to explain the new concept.) Since only the part expressed by adding a stereoscopic projection such as a perspective view can be projected out of the others and stereoscopically viewed, the display surface can be electrically, f-elements, discharge, voltage, electromagnetic, particle, video, and image signals Image processing for the front and the back and time-division display, so that a flicker with the naked eye can be seen in a wide field of view. In other three-dimensional image processing devices, in the neon signboard, the front rooster image display neon tube and the rear image display neon tube are attached to the same display signboard surface, alternately front and rear, time-divisionally, and forward. Combined with discharge light emission from only one of the rear side, flickering with the naked eye from a distant and wide area, color and spatial resolution are not reduced, and solid and plane are repeated instantaneously, so it is better than other neon signs You can see the neon signboard that stands out. In the case of a rotating signboard holding a three-dimensional image using wind power, a three-dimensional processed image similar to that in Experiment I is held on the display unit, so that when the signboard is rotated by the wind, the three-dimensional object stands out. An image can be obtained.

In addition, the two-dimensional fusion, the two-dimensional fusion, and the two-point fusion, the two-point fusion, and the two-point fusion method are combined with each other. As a method of creating a rooster image processing display device, in addition to the above-described two-time fusion and two-hour eye fusion methods, it is necessary to arrange the surface image display surface having high transparency. In a movie, three screens are arranged as shown in Fig.2G using instantaneous light control glass using liquid crystal, and the voltage is turned off only on one screen surface to provide a white screen display surface. In other cases, 95% light is transmitted by applying a voltage, and one screen is used for each unit of each image, and three screens are displayed and cycled with the voltage turned off. One screen surface rotates or flies face-to-face by the lean switch switching processing drive circuit. By displaying the working circulation as usual, or by rotating one screen line-symmetrically or point-symmetrically (see Fig. 2W, X), the speed is reduced or reduced every time the image is displayed. By temporarily stopping and rotating at high speed at other times to reflect the projected image, or by forming a triangular prism with three screens and forming the Q, S, and S types by rotation, a display phase difference is created. In this case, a rotation speed switch switching processing circuit that switches to a pause or low-speed rotation to display one frame of each video and a switch switching video frame synchronization processing output circuit device, and a lenticular lens sheet is used. of In the screen, as shown in Fig. 2T, a lenticular lens sheet is attached to the reflective display surface, and a lenticular concave lens sheet having the same type of concave part that becomes completely transparent when the convex and concave parts overlap with the convex lens is attached to the back side of the screen. Thus, it is possible to completely transmit and emit the incident light from behind without giving directivity, and it is possible to similarly perform each diagonalization of the screen without using the lens. In the case of a lean screen, the center seat uses three screens, and the left and right seats use two screens. In the triangular prism screen, each image of the vacant layer, the vacant layer, the vacant layer, and the vacant layer with the naked eye can be obtained by the three faces in all three directions. Glass Changed to a self-luminous EL element color display with high transmissivity (the EL light emitting section is sandwiched between transparent electrodes and the edge layer from both sides to provide transmissivity). A processing circuit for associating pieces (two interlaced scans) and outputting the video signal for each grave to each EL element display surface, and a signal output from a drive circuit portion in the processing circuit by a switch circuit. By connecting and displaying in synchronization with the output from the processing circuit, or by bonding two thin displays, such as an EL element and a liquid crystal with S 'backlight, with the display surface outside and Each set is rotated in the same way as the above, and when the disc array is one (the liquid crystal light source is placed outside the rotation range of the line and point symmetry), when the back display surface is visible, it is a mirror image. Apply the same rotation as the movie while switching A triangular prism with the display surface facing out is formed by any one of three elements, liquid crystal, and CRT, and the lenticular lens sheet is used in the same configuration as the movie, and the rotating display is the same as the movie. If you do this, you can see each of the three-dimensional objects with the naked eye from three horizontal directions (when there are three pieces and a triangular prism), horizontal 360 degrees (when one set of two pieces), or 180 degrees (when one piece). The images can be observed, and in Fig. 2 W and X, the image observation from the 45 degree sky is different from the display image due to the difference in the observation phase space position. Deviation DEF is generated and fusion cannot be performed, but the rotation axis, the display position of the displayed image is shifted, or the image display position is shifted due to the stepwise difference in the refractive index of the semi-dome shaped lens. With the above combination, fusion can be achieved by eliminating the difference DEF between the two rooster images of the display and observation. In particular, if the single dome-shaped lens is used alone, the right and left sides of the hemisphere will be 180 degrees. The image can be stereoscopically viewed from an inside direction of 90 degrees before and after (hereinafter, the stereoscopic image obtained by the above method is referred to as a virtual empty image).

 To give a simple example of obtaining an imaginary rooster image in only one direction, in Fig. 8, two cathode ray tubes 1 15 and one EL element screen 1 16 and a half mirror 1 1 7 are used. Image display processing that is arranged as shown in Fig. 8 and displayed on one display screen for each video frame unit, and one frame at the next time is displayed on another display screen and circulated regularly. A virtual layer image can be obtained by the connection display from the switch switching circuit.

In addition, the reason that the monocular stereovision can be performed is the vision performed by this method in the optic nerve intersection and the visual center, and the monocular is considered to function as a window for information. In addition, the least fatigue of eye movement is the spatio-temporal fusion in which the same motion is applied to both eyes evenly.In the case of the spatio-temporal eye fusion that can obtain a high stereoscopic effect, the advantage of the binocular fusion is divided into 30 seconds. If it is ensured by performing in step 1 and the left and right exchange is performed in a short time not less than the above time and the circulation is performed, the advantage of both-time fusion can be utilized. Next, referring to FIG. 7A, a three-dimensional image processing apparatus, which is a simple example of binocular fusion, will be described. A cushioned headband 102, which can be adjusted according to the shape of the head of each person, 10 3, a frame 10 4 which is protruded so that it can be used by being overlapped with a pair of spectacles, a viewing angle adjustment knob 105 which can raise and lower the frame, and the present eyeglass device The left and right images are exchanged by half a turn.The panel contraction force of the screw with the center point panel for rotation and the three side points of both side bow-shaped concave and convex portions 101 or the magnet force is applied to stabilize at 1 o'clock and the top and bottom. Invertable lens A frame part 100, a knob 95 that can move left and right a cylindrical lens concave and convex behind two thin lenses for changing the image forming position in front of the observer, and the lens A cylindrical lens with a polarizing filter, an adjustable knob 96 that can change the gap between the concave and convex integrated sheet 97, a light-shielding cover hood 98 that prevents light from the horizontal and vertical directions, and light inside the glasses. This is a three-dimensional image processing spectacle device that uses a dark black color with little reflection.

 Next, referring to FIG. 7B, a description will be given of a simple example of an image stereoscopic eyeglass device using the binocular fusion method. The image light 81 incident from the upper window at one time is refracted. The light passes through the rate adjustment algorithm 82 and is turned on at one point when the voltage is turned on (light is shut off when the voltage is turned off at the first point of time). Rear-cylindrical convex mirror 84 A half mirror 90, which is processed into a rearward image that is compressed in the horizontal direction by 4 4 and is tilted to 45 degrees or less, and then refracts to the center so that it becomes one image on the left and right after reflection 9 1 Transillumination observation On the other hand, the image light 86 at the primary time is processed into a frontal image that is enlarged in the horizontal direction at the time when the cylindrical lens concave and convex at 87 and 88, respectively. Instantaneous dimming when voltage is turned on at the point in time (surface image light 86 does not enter due to voltage off at the previous point in time) After passing through the glass 89 and 45, the half mirror 89 and the prism 90 tilted at an angle of less than 45 degrees, they are projected to the eyes 85 of the observer 1 and the afterimages 8 1 and 8 6 at the first time and the first time are obtained. It will be able to be merged and stereoscopically viewed. In addition, the inside of the glasses is made dark black finish with little reflection and the inclination angle of the half mirror 90 is set to 45 degrees or less to increase the reflectance and reduce the amount of transmitted plane image light 86. It is also characterized by the ability to obtain the mirror effect without the need for it. Also, instead of the prism 82, a cylindrical lens 8 8, 8 7 that can be processed into a rear surface image is attached, and a cylindrical convex mirror 8 4 Can be changed to a plane reflector and used.

 Further, in FIG. 7C, the image light 81 at one point in FIG.

The image information captured by the image processing unit 120 and processed by the image By displaying an image using the television set 122 and the optical lens 122, it is possible to form a three-dimensional figure as in FIG. Industrial applicability

 As described above, according to the present invention, since the planar image processing field can enter the stereoscopic image processing field, by utilizing the planar image processing field, the stereoscopic image processing field can be newly started from scratch. Time to build up ■ Spatial • Economical · Industrial culture Elimination of enormous losses from birth.

 In particular,

Plane image information holding materials for home use or home use or for business use (Plane photographs, Plane photograph collection, Plane aerial photograph, Plane art photograph collection, Plane catalog, Plane mail order catalog, Plane flyer, Plane pamphlet, Plane newspaper, Plane Weekly magazines, collection of flat guides, flat color books, flat posters, flat calendars, flat magazines, flat books, flat maps, 3D plan drawings, 3D plan designs, flat houses and buildings completed drawings, flat photo albums, flat Slide photo, 2D picture book, 2D TV software, 2D PC software, 2D text broadcasting software, CD / LD ■ Magnetic-magneto-optical 2D disk software, 2D video tape software, 2D digital tape software, 2D plane Movie software, planar video game software, planar movie film, planar microfilm, planar radiograph, planar CD ROM soft, flat computer graphics soft, flat painting, flat rooster, flat illustration, flat mural, flat sign, flat rotating sign, flat display surface of various measuring instruments, household appliances ■ Sound equipment · Communication equipment · Medical equipment · OA equipment ■ PA equipment-FA equipment · Planar display surfaces of various terminals, planar characters using stereoscopic projection · Numbers-symbols · codes · patterns, and other planar image information holding objects) can be viewed stereoscopically. Even if there is no mouth and three-dimensional object, if there is a two-dimensional image information holding object, the rooster image can be three-dimensionally processed. Alastifi Film Film Discharge Lamp Fluorescent Tube Fluorescent Light Emitting Diode ■ Optical Fiber Integrated Laser Light ■ Electroluminescence, Plasma, Diamond Thin Film, EL Device, Ceramic Thin Film. Fas silicon, electricity, voltage, electric field, electron, electromagnetic wave ■ radio wave, electric discharge, magnetism, ripening, ultraviolet rays, particle beam, fog, steam, water, ice, snow, clouds, bubbles, image processing using any of seawater Planar image processing equipment to display, glasses, binoculars, telescopes, microscopes, magnifiers, cameras, video cameras, TV cameras, aerial photography cameras, medical cameras, cinematographers, projectors, projectors, and movie images Image processing equipment, cinemas, cinemas, dome-type cinemas, cine-films, screens, monitors, video monitors, portable video Monitor

, Pocket TV, TV integrated video, seat vision, videophone, power TV, car navigation system, wall TV, black and white TV, color TV, LCD TV, LED display, medical TV, wireless · Atmospheric wave broadcasting TV, teletext broadcasting, facsimile broadcasting TV, data broadcasting TV, cable broadcasting TV, captain system TV, PC communication TV, satellite TV, high-vision broadcasting TV, optical fiber broadcasting network Televisions, multimedia televisions, video game machines, car televisions, video conferencing systems, crime prevention and disaster prevention televisions, home information system televisions, fashion shows, concerts, and events. Commercial disk Play, Video recorder for TV, Disc recorder for TV, Notebook PC, Raptoza PC, Copy machine, Electronic system organizer, Pocket computer, Large-sized conveyer, Computer for image processing, Warp port, Oscilloscope, Handy Terminals, industrial control systems, POS terminals, financial terminals, counter business terminals, OHP panels, business measurement equipment, ultrasonic flaw detectors, sonars, ultrasonic diagnostic equipment, X-ray diagnostic equipment, ultrasonic Tomography equipment, medical measuring instruments, sphygmomanometer, electronic thermometer, personal radio, facsimile, workstation, word processor, information display, video communication terminal, portable information terminal, pen input terminal Appliances, audio, VTRs, electronic musical instruments, cooking utensils, air conditioners, various remote controls, neon signboards, illuminated signboards, electric bulletin boards, other display devices, and other industrial planar image processing devices). With only a little devising each processing device, various practical stereoscopic image information can be obtained immediately, and the cost can be reduced.

C. Movies and photos. When shooting images for TV, two cameras for the left and right eyes are not required, and only one camera is required.

Second, natural color screens can be obtained with stereoscopic image processing glasses.

E. With the current television broadcasting, there is no need to add broadcasting equipment and there is no cost.

In the current TV broadcast, it is not necessary to secure the transmission and reception of two channels for the left and right eyes, and the current transmission and reception of one channel is sufficient.

In the current TV broadcasting, the stereoscopic effect of the stereoscopic image can be reduced to zero or increased or decreased, so that the current television and the stereoscopic image processing television can be compatible.

H, a video desk for stereoscopic image processing television and a projector for stereoscopic image processing are unnecessary, and existing video desks and existing projectors can be used.

Requiring no special software for stereoscopic image processing television and special software for stereoscopic image processing movies, the existing software can be used.

(2) A beautiful image with almost the same flickering color and spatial resolution as the current planar image processing device can be obtained.

As with the current flat-panel image processing equipment, a wide field of view can be secured, so that families or groups can enjoy stereoscopic images.

に お い て In the fusion method with “eye” and “place”, Lenty Kyura lens plate and each The observer voluntarily moves his or her head to the left or right in stereoscopic viewing (eg, photography, television, movie) with the naked eye using a display device in different directions on the stacked EL element screen with left and right lenses in different directions. By reversing the top and bottom of the surface, or by changing the front and rear display surfaces and the left and right display surfaces and each display image back and forth, left and right, the feeling of eye fatigue can be reduced and `` eye '' In the fusion where “place” and “sky” are attached, the focus can be moved, so that the feeling of fixed visual fatigue that keeps the focus fixed for a long time can be reduced. In the fusion method where “time” is attached, the stereoscopic / planar image processing table is used. Display devices (screens, televisions, various measuring machines, lightning and liquid crystal clocks, neon signs, rotating signs, electronic signboards) The fatigue of both eyes at the same time in the opposite direction In the fusion method in which the reduction is measured and the other eye can be rested spontaneously by stereoscopic vision with only one eye, and the fusion method in which “sky” is attached to “time”, the focus shifts with both eyes simultaneously (fixed vision fatigue). Feeling can be reduced), and a balanced and unbalanced fatigue can be obtained, so that stereoscopic viewing can be performed for a longer time than conventional methods.

ヮ A myriad of stereoscopic images according to image software (action images, news images, landscape images, etc.) can be created and selected by various rooster image processing methods.

In the fusion method where force, “time” and “sky” are attached together, a holographic image (fusion 融, binocular parallax, monocular parallax, and focus adjustment can be performed), a vacant layer rooster image, a vacant layer image, a vacant layer Standing rooster image, imaginary layered image (fusion 铴, left / right / up / down vanishing point perspective fusion, monocular motion parallax, focus movement possible, fusion with “time”, “sky” and “vision” (Even parallax fusion can be performed), and all three-dimensional objects (landscapes, moving roosters) and planar images can be viewed stereoscopically from practical multiple directions in the sky and high practicality, low cost, and high-performance It seems to be a three-dimensional image. In each fusion method with “Eye” and “Place”, the three-dimensional image information holding display printed matter ( (Right / left image parallel, left / right image fusion, 3D stereogram, random pattern) can be used for stereoscopic viewing with both viewpoint parallel methods. Because it can be obtained, and by combining it with the conventional binocular parallax (the same applies to other processing devices and the same display object), the stereoscopic effect can be further enhanced.

In the fusion method where “time j” is added without “sky”, facsimile broadcasting, data broadcasting, captain system broadcasting, For CATV broadcasting, all households of the contracted member offices, for atmospheric radio wave TV broadcasting and teletext broadcasting, all households in all receiving offices in all homes, and for satellite broadcasting and high-vision broadcasting, all domestic reception When three geostationary satellites, evenly arranged in a circular orbit of 36,000 km above the equator, in all the vehicles in all the offices of the business establishment, receive satellite broadcasts using satellite geography broadcasting as the amplification point during amplification The whole world can be covered with microwaves, and the Olympics in summer and winter can be viewed stereoscopically in all homes and vehicles in all offices and countries around the world, making it possible to contribute instantly to the spread of stereoscopic image culture.

Re: A 3D image can be produced simply by installing an image 3D processing device using the fusion method with the “time” in front of existing cameras and existing projectors. Images can be manufactured, and private photos taken in the past · The film · The plane images of the theater can be enjoyed stereoscopically, contributing to the culture of creating stereoscopic images at the individual level.

Seo, in the existing TV commercials that combine “simultaneous two-hours”, if the product names are displayed separately, only the product names remain in the impression and the CM effect can be improved. In the use of this method for medical and industrial purposes, it was difficult to read the three-dimensional structure from the X-ray photograph in the X-ray photograph. Similarly, the diagnosis of tomography in the human body in medicine can be performed in a short time with high accuracy of information analysis. Even a woman can face the fetus three-dimensionally, which can contribute to alleviating the anxiety of childbirth.In addition, remote control using a screen requires difficulties without skill because of the flat screen operation. Because it is possible to grasp three-dimensionally, it can be operated immediately and easily, and it is easy to grasp the internal structure and the state of internal emulsification and liquefaction in industrial metal ultrasonic flaw detectors, ultrasonic tomographs and sonars. Can be contributed.

The ability to grasp three-dimensional radar information in the ultrasonic radar control system can contribute to speeding up information recognition, improving accuracy, and increasing reliability several times.

By using this method, it can be used as a means to three-dimensionally consider chemical substances, stereochemistry, and the arrangement of atoms in molecules in natural science and explain various phenomena in three dimensions. La, It can be used as a means of studying spatial figures in solid geometry.

It can be used to grasp the initial three-dimensional image in the production of images and bronze statues.

ゥ, Binocular fusion, Binocular spatiotemporal fusion, Binocular spatiotemporal fusion, and Binocular spatiotemporal fusion, a gospel that can be stereoscopically viewed even for monocular and monocular amblyopia, and enjoy a stereoscopic effect. No. A new interpretation of the stereoscopic structure at the optic nerve crossing and the visual center will open up new ways and enhancements in visual therapy and visual enhancement training in medicine. Along with the increase in the number of people living at home in an aging society, etc., creating a virtual imagery group with extremely high virtual reality makes traveling at home without danger · Same medical treatment ■ Same shopping · Same duty The same conference. The same museum. The same zoo. The same botanical garden. The same library. The same park. The same amusement park. The same performance. The same concert. The same fashion. The same sumo wrestling. The same competition. The same parade. Can greatly contribute to home welfare that can be enjoyed with peace of mind.

H, the virtual reality experience in the previous item “o” can be contributed to experience in the rooms of libraries, hospitals, medical facilities, various classrooms, and amusement facilities.

In the omnidirectional multimedia using stereoscopic images, this method uses a terminal. Since high-speed image processing utilization display is required, image reproduction using only the digital method causes further difficulties in ultra-high-speed image processing technology in the next three-dimensional utilization display. Therefore, the method that combines the advantages of analog and digital is the center of this method (it seems to be a reasonable conclusion even from the viewpoint of historical axioms). The time and capital invested in the development of the MUSE method -Effort · Contribute to directly utilize intellectual property.

Image software that can be used by multi-disciplinary software because the advantages of the software and the multi-disciplinary software can be used by the user or the hardware has not yet emerged. The specification range has not been determined. With the release of this method, a hardware that can be compatible with 3D benefits and 3D software could be constructed free of charge between the human visual center and existing hardware that is widely used in various fields. As a result, the world's largest hardware has already emerged, and it is possible to move forward to the establishment of the standard range, and to contribute to saving the immense waste in the history of international industrial development.

Ke, conventional binocular parallax ■ With the holographic method, stereoscopic vision of a three-dimensional object that does not exist in the past was impossible semipermanently unless it was a time machine. In this method, if the above-mentioned three-dimensional object is stored and inherited as a rooster image information holding object, it can be stereoscopically viewed, so it is an unexplored and exciting experience of experiencing a vast and vast planar artifact from the past. A diverse group of doors to the past has opened, rewarding those who have retained the common heritage of mankind, and contributing to the further development of the feat.

By utilizing these methods, the three-dimensional image information holding material overflows not only in Japan, but also in every corner of the world, and is expected to be enjoyed in daily life as a matter of course. By utilizing the plane image information holding related objects, the distance to life can be reduced by 30 to 50 years, and it can contribute to eliminating waste of time.

Based on the above, it can be said that the practical effect is great. Description of reference numerals in the drawings

 1 observer, 2 left eye, 3 right eye, 4 visual center, 5 rear image, 6 front image, 7 rear sense image information, 8 front sense image information, 9 fusion image, 10 stereo depth, 11 front sense, 12 Backward feeling, B warm color, 14 cool color, 15 dark color, 16 light color, 17 light, 18 dark, 19 hard focus, 20 soft focus, 21 large image, 22 small image, 23 Image system, 24 No image system 25, 26 Color monitor 1, 27 mirror, 28 Video recorder, 29 Teletext receiver, 30 Video camera, 31, 35 Circular convex lens, 32, 34 C Lenticular concave lens, 33 image stereoscopic processing glasses, 41 front image, 42 rear image information, 44 lenticular lens plate, 45 lenticular lens, 51 right eye image, 52 left eye image, 3 Forward feeling image information, 54 Back feeling image information, 55 Fusion image, 61 Image display, 67 Forward feeling movement, 68 Rear feeling movement, 71, 75 image light, 72 cylindrical Lenses, 73 cylindrical concave lenses, 74 screens, 76 mirrored shutters, 77, 78 mirrors, 79 convex mirrors, 80, 82, 91 refractive index adjustment prism, 81, 86 image light, 83 , 89 Instantaneous dimmer, 84 convex mirror, 85 binoculars, 87 cylindrical convex lens, 88 cylindrical concave lens, 90 h mirror, 95 movement adjustment between left and right lenses,% movement adjustment between front and rear lenses Knob, 97 cylindrical lens concave and convex integrated sheet, 98 hood, 100 top and bottom inverted part, 101 bow-shaped uneven joint, 102, 103 headband 104 cavity for widespread eyeglasses, 105 viewing angle adjustment knob, 115 CRT, 116 EL element screen, 117 half mirror, 120 CCD camera, 121 liquid crystal screen, 122 optical lens, 123 image processing device, 130 left eye image, 131 right eye image, 132 rear sense image, 133 front Feeling image, 134 fusion image, 140 display image, 141 display observation image, 1 42 Right eye image, 143 Left eye image, 145 Forward image, 146 Fusion image 147 Rear image, 150 Display image, 151 Front image, 152 Rear image, 153 Fusion image, 154 Forward image, 155 Rear image, 156 Fusion Image, 157 forward image, 158 rear image, 159 fusion image, 160 color monitor, 161,261, 361, 461, 561 image display unit. End <

Claims

The scope of the claims

1. In the image information display unit of the image information holding object, and in the image information display unit in which the image information display unit is transparent and transmitted, the same type of image information signal or the same type of the image to be displayed image information, respectively. In comparing information between the image information beams, or the image information output unit, the processing unit, the recording / reproducing unit, the storage / reproducing unit, the reproducing unit, the recording unit, or the storing unit of the image information holding material , The same type of image information signal of the same image information output, the same processing, the same reproduction, the same recording, or the same stored image, or the information comparison between the same image information light An image shape information signal of an image having the same shape as the above, or the information light, two or more monocular photographing points, two or more monocular viewpoints, and two or more assumed monocular viewpoints each eye of binocular parallax Image for observer's correspondence The phase spatial information signal of the image observation point when the image is projected over the entire time corresponding to each eye, or the same kind of image information signal except for the information light and the information light or the information between the information light In comparison, an image information signal having at least one kind of difference, or an image shape information signal of an image having the information light, or an image shape information signal of an image in the case of forming the same shape as the above method, or the information. A light, a phase space information signal of an image observation point when an image is projected over all time points corresponding to the respective eyes of the observer, or the same kind of image information of the same type of the information light. An image information signal having a difference in the information comparison, or an image information signal having the one or more kinds of each of the information light, or an image information signal having the information light being added to the information light, respectively; or 3D image information characterized by having information light Information holdings.

2-The image information holding unit is an image information display unit, image information recording / reproduction unit, image information storage / reproduction unit, image information reproduction unit, image information processing unit, image information recording unit, image information storage unit, or image information in the output section, any one or more, characterized in that it is a composed image information retentate in claim 1, wherein the 3D image information _retentate:

3. The image information display section, the recording / playback section, the storage / playback section, the playback section, the processing section, the output section, the recording section, or the storage section of the image information holding object is composed of two or more monoculars. Whether the image for each eye at the shooting point, two or more monocular viewpoints, and two or more assumed monocular viewpoints is an image common to each eye at one point in time, or an image for each eye with the left and right eyes interchanged, Or, as the image for each eye, where the left and right eyes have been replaced at the next multiple time points to the one time point image, or as an image common to each eye, the image information display, the same reproduction, the same processing, the same output, the same recording, or Each of the units that are stored in the same memory, or an image common to each eye at 1 monocular photographing point, 1 monocular viewpoint, and 1 assumed monocular viewpoint at each point in time, an image for each eye, or an image common to each eye Or the image at one time point is used as an image common to each eye at the next multiple time points, or as an image for each eye. The information display, playback, same processing, same output, same recording, or the same part that stores the same, or the image information holding material composed of at least one of the following, or the image information holding material The image information display section is a flat body, a parallel body, a parallel fusion body, a laminate of two or more layers, an inclined body, a curved body, a cross body, a rotating body, a cylindrical body, a polyhedron, a radial body, a disk body, and a line symmetric body. , Point symmetry, optical element, optical fiber, film, photosensitive material, and / or paper One or more, one part, multiple parts, one surface, or all or all of the image information display part 3. The stereoscopic image information carrier according to claim 1, wherein the image information display unit is an image information display unit that can be exchanged for another image information display unit.

4. The images are each monocular image, each monocular shared image, each monocular fused image, forward image, backward image, forward and backward shared image, forward and backward fused image, one time point image, each multipoint time image, one direction Any one or more of a phase space image, each multi-directional phase space image, a real image, a virtual image, and a real image / virtual image fusion image, or the image is different from the other images The stereoscopic image information holding material according to claim 1, wherein the image is an exchangeable image.

5. The same kind of image information signal and each information type of the information light are hue information, saturation Information, luminance information, color and image aberration information, image image shape information, image presence information, image observation point phase space information, and non-correlated phase space information between display images and display observation images Each information type or the signal of the image information signal is a magnetic signal, an electric signal, an electromagnetic signal, an electromagnetic wave signal, an optical signal, a light wave signal, an electronic signal, a discharge signal, an ultrasonic signal, a particle beam signal, and 3. The stereoscopic image information carrier according to claim 1, wherein the signal is a signal composed of at least one of a video signal and a video signal.

 6-an image information signal having a difference, and the information light having a difference capable of increasing or decreasing the level of the difference, or the level of the ratio of the difference, or reducing the level of the difference to zero The stereoscopic image information carrier according to claim 1, wherein the information light is an image information signal and the information light.

7. In the image information display unit of the image processing device, and in the image information display unit in which the image information display unit is transparent and transmitted, the same type of image information signal or the same type of image displayed on the image information, respectively. In comparing information between information beams, or from the image information output unit, the processing unit, the recording / reproducing unit, the storage / reproducing unit, the reproducing unit, the recording unit, or the storing unit of the image processing apparatus, In the image information output, the same processing, the same reproduction, the same recording, or the same type of image information signal of the stored image, or the same information as the varifocal mirror system in the information comparison between the image information beams The image shape information signal of the image in the case, or the same information light, two or more monocular imaging points, two or more monocular viewpoints, and two or more assumed monocular viewpoints for each eye image of binocular parallax For each corresponding eye The phase spatial information signal at the image observation point when the image is projected over the entire time corresponding to each, or the information light and the same type of image information signal except for, or the information comparison between the information lights An image information signal having at least one kind of each difference, or an image processing device provided with the information light, or an image shape information signal of an image in the case of forming the same shape as the above method, or Each of the information light and the corresponding eye of the observer is paired. Accordingly, the phase spatial information signal of the image observation point when projecting an image over all time points, or the same information light and the same kind of each of: the image information signal having a difference in the information comparison between the information, or An image information signal having the at least one kind of each of the information lights, or an image information signal obtained by adding the information light to each of the information lights; or an image processing apparatus including the information light. A method for manufacturing a stereoscopic image processing device, comprising:

 8. The image processing device is an image information display unit, image information recording and playback unit, image information storage and playback unit, image information playback unit, image information processing unit, image information storage unit, image information storage unit, or image information output unit. 8. The method for manufacturing a three-dimensional image processing apparatus according to claim 7, wherein the method is an image processing apparatus including at least one of the above.

9. The image information display unit, the recording / playback unit, the storage / playback unit, the playback unit, the processing unit, the output unit, the recording unit, or the storage unit of the image processing device has two or more monocular images. Point, two or more monocular viewpoints, and two or more assumed monocular viewpoint images for each eye at a single point in time, or an image for each eye with the left and right eyes interchanged, or The image for each eye, which is replaced with the left and right eyes at the next multiple time points, or the image common to each eye, and the image information display, the same reproduction, the same processing, the same output, the same recording, or Each of the parts that are stored in the same memory, or one monocular photographing point, one monocular viewpoint, and one assumed monocular viewpoint common image for each eye at one point in time, or a common image for each eye Or the one-time image is used as an image common to each eye or an image for each eye at the next multiple time points. Display, reproduction, processing, output, recording, or storage, the image processing device including at least one of the following, or the image information of the image processing device. The information display section is a flat body, parallel body, parallel fusion body, two or more layers of stacked body, inclined body, curved body, cross body, rotating body, cylindrical body, polyhedron, radial body, disk body, line symmetric body, point Symmetric body, mirror, glass, plastic, optical element, liquid crystal, dimming plate, Brass tube, E element, discharge lamp, light emitting diode, fluorescent tube, light emitting body, optical fire Bars, electorum luminescence, plasma, diamond thin film, screen, film, photosensitive material, gaseous state, liquid state, solid state, crystal state, particle state, and , One or more of paper, an image information display unit that forms one, multiple, one, or all of the paper, or the image information display unit is another image information display unit 8. The method for manufacturing a stereoscopic image processing device according to claim 7, wherein the image information display unit is an image information display unit that can be replaced with a unit.

 10 .The images are single-eye images, single-eye shared images, single-eye fused images, forward images, backward images, forward-backward shared images, forward-backward fused images, one-point images, multiple-point images, one-way images Any one or more of a phase space image, each multi-directional phase space image, a real image, a virtual image, and a real image / virtual image fusion image; or 8. The method for manufacturing a three-dimensional image processing device according to claim 7, wherein the images are exchangeable.

 1 1. The same kind of image information signal and each information type of the information light are composed of hue information, saturation degree information, luminance information, color and image aberration information, image shape information, image existence information, image observation. Each type of phase space information of a point and uncorrelated phase space information between a display image and a display observation image, or a signal of the image information signal is a magnetic signal, an electric signal, an electromagnetic signal, or an electromagnetic wave. Signal, an ultraviolet signal, a light signal, a light wave signal, an electronic signal, a discharge signal, an ultrasonic signal, a particle beam signal, and a video signal. A method for manufacturing a three-dimensional image processing apparatus according to claim 7.

 12. An image information signal having a difference and the information light indicate a difference that can increase or decrease the level of the difference or the level of the ratio of the difference or reduce the level of the difference to zero. 8. The method for manufacturing a three-dimensional image processing apparatus according to claim 7, wherein the information light has an image information signal and the information light.

13. In the image information display unit of the image processing device, and in the image information display unit where the image information display unit is transparent and transmitted. In the comparison of information between the same type of image information signal or the same type of image information light of the image to be output, or the image information output unit, the same processing unit, the same recording / reproducing unit, the same storage / reproducing unit, the same reproduction of the image processing device Image information output, the same processing, the same reproduction, the same recording, or the same type of image information signal of the stored image, or the same image information light from the same unit, the same recording unit, or the same storage unit, respectively. In the information comparison of the above, the image shape information signal of the image in the case of forming the same shape as the varifocal mirror method, or the information light, two or more monocular photographing points, two or more monocular viewpoints, and two or more The phase space information signal of the image observation point when the images for each eye of the binocular parallax of the assumed monocular viewpoint are projected over all time points corresponding to the respective eyes of the observer, or Information light and the same kind of image information signal except, or An image information signal having at least one kind of difference between the information light beams, or an image processing device provided with the information light beam, or an image of an image in the case of forming the same shape as the above method A shape information signal, or the information light, and a phase space information signal of an image observation point when an image is projected over all time points corresponding to the respective eyes of the observer, or the information. The image information signal having a difference in the information comparison between the same type of image information and the image light signal, or the image information signal having the one or more types of the respective differences, or the information light, respectively. An image three-dimensional processing apparatus, characterized in that it is an image processing signal provided with the added image information signal or the information light, respectively.

14. The image processing device is an image information display unit, an image information recording and reproducing unit, an image information storing and reproducing unit, an image information reproducing unit, an image information processing unit, an image information recording unit, an image information storing unit, or an image information. 14. The three-dimensional image processing apparatus according to claim 13, wherein the three-dimensional image processing apparatus is an image processing apparatus including at least one of the output units.

15. The image information display unit, recording and playback unit, storage and playback unit, playback unit, processing unit, output unit, storage unit, or storage unit of the image processing device are two or more monocular An image for each eye at the photographing point, two or more monocular viewpoints, and two or more assumed monocular viewpoints is shared by each eye at a single point in time, or an image for each eye with the left and right eyes replaced. Or as an image of each eye that has been replaced with the left and right eyes at the next multiple time points, or as an image common to each eye, at the next multiple time points, or as an image common to each eye. Each part that is recorded or memorized in the same way, or one monocular imaging point, one monocular viewpoint, and one assumed monocular viewpoint common image for each eye at a single point in time, or for each eye Or the image at one point in time is displayed as an image common to each eye or an image for each eye at the next multiple time points, and the image information is displayed, reproduced, processed, output, and recorded. Or each of the units that store the same, or an image processing device including at least one of the following, or an image information display unit of the image processing device includes a planar body, a parallel body, a parallel fusion body, Stacks of two or more layers, inclined bodies, curved bodies, cross bodies, rotating bodies, cylindrical bodies, polyhedrons, Body, disk, line symmetry, point symmetry, mirror, glass, Alastik, optical element, liquid crystal, dimming plate, brown tube, E-element, discharge lamp, light emitting diode, fluorescent tube, Light-emitting body, optical fiber, electorum luminescence, plasma, diamond thin film, screen, film, photosensitive material, gaseous state, liquid state, solid state, crystal state An image information display unit that forms at least one part, multiple parts, one surface, or all of at least one of an object, a particle state object, and paper; or 14. The three-dimensional image processing apparatus according to claim 13, wherein the three-dimensional image processing unit is an image information display unit that can be exchanged for another image information display unit.

 16. Each image is a single-eye image, a single-eye shared image, a single-eye fusion image, a forward image, a rear image, a forward-backward shared image, a forward-backward fusion image, a one-point image, each multi-point image, and one direction. Any one or more of a phase space image, each multi-directional phase space image, a real image, a virtual image, and a real image / virtual image fusion image; or 14. The image three-dimensional processing device according to claim 13, wherein the image is an exchangeable image.

17. The same type of image information signal and each information type of the information light are composed of hue information, saturation information, luminance information, color and image aberration information, image image shape information, and image presence of an image. Information, the phase space information of the image observation point, and each type of information of the decorrelated phase space information between the display image and the display observation image, or the signal of the image information signal is a magnetic signal, an electric signal, The signal must be at least one of an electromagnetic signal, an electromagnetic signal, an ultraviolet signal, an optical signal, an optical signal, an electronic signal, a discharge signal, an ultrasonic signal, a particle beam signal, and a video signal. The three-dimensional image processing apparatus according to claim 13, wherein:

 18. The image information signal having the difference and the information light indicate the difference that can increase or decrease the difference or the ratio of the difference or reduce the difference to zero. 14. The image three-dimensional processing apparatus according to claim 13, wherein the image information signal has the information light and the information light.

 1 9. The image information processing section is composed of any one or more optical elements among optical elements that can enlarge, reduce, reflect, transmit polarized light, transmit polarized light, semi-transmit, transmit, or refract. A switching unit capable of switching between image information input or image information signal at each time when image information is input or image information of the information light, opening and closing, and simultaneous splitting opening and closing, and driving for driving the switching unit 2. The image processing apparatus according to claim 1, further comprising: a switching circuit unit, an image information output unit that outputs the image information signals or the information light, or an image information display unit that outputs the image information. 3. The image stereoscopic processing device according to 3.

20. The image information processing unit is composed of one or more optical elements among optical elements capable of enlarging, reducing, reflecting, transmitting polarized light, transmitting polarized light, semi-transmitting, transmitting, or refracting, Image information input, or each time point image information signal that enters the image information, or the said information light, for each eye of the real image that the observer is observing, or each time point image information light shared by each eye, As the image information signal for each eye or for each point in time shared by each eye or the information light, the image information signal or the image information of the information light is opened, closed, and simultaneously. A switching unit capable of switching between divided opening and closing, a drive switching circuit unit for driving the switching unit, and the image information signals; 14. The three-dimensional image processing apparatus according to claim 13, further comprising: an image information output unit that outputs the information light or an image information output unit that outputs the image light.

 21. Covers the headband and the popular eyeglass that can be changed according to the shape of the observer's head. The cavity that can be used with the glasses, the knob that can adjust the visual direction angle, and the internal reflected light 14. The three-dimensional image processing apparatus according to claim 13, further comprising a color finishing part capable of absorbing light and a hood part for preventing incidence of external light.