KR930005476B1 - Three dimensional image recording reproducing apparatus and manufacturing method thereof - Google Patents

Abstract

The method for recording and reproducing the clean 3- dimensional image simply and effectively without using the laser beam or polarizing filter involves recording optical information of right image and left image taken of a subject changing an optic angle e.g. of a picture in a frame of a film, without a simultaneous overlap of the left and right 3-dimensional optical information, so that they can be alternately arranged. This is followed by revival into a 3-dimensional image. Collimated optical information is passed through a multiple slit grating (8') to resolve it into two components.

Description

Stereoscopic image recording and playback device and method

1 is a perspective and sectional view of a camera equipped with a conventional stereo photo adapter.

2 is a conventional stereo photograph taken of a subject by a stereo camera or a camera to which a stereo photograph adapter is attached.

3 is a perspective view of a stereo view.

4 is a cross-sectional view and amplitude distribution diagram of the next slit grating.

5 is a cross-sectional view and amplitude distribution diagram of a photographic dry plate grating.

6 is a diagram for explaining the configuration of a three-dimensional camera for implementing a three-dimensional image of an embodiment of the present invention.

7 is a state diagram showing that when the collimated optical information passes through the multi-grid slits grating, the optical information is divided into three-dimensional optical information of two components and arranged alternately without overlapping.

8 is a stereo photograph adapter modified in order to apply a conventional stereo photograph adapter to the present invention.

9 is a comparison diagram of the positive film produced by the stereo camera and the positive film on which stereoscopic optical information according to the present invention is recorded.

10 is a state diagram showing a stereoscopic movie using a positive film having a stereoscopic information made by the present invention.

11 is a configuration diagram of a stereoscopic TV camera and a stereoscopic video camera according to one embodiment of the present invention.

12 is a block diagram of a three-dimensional television receiver of a trinescopy system of one embodiment of the present invention.

13 is a block diagram of a reflective stereoscopic television receiver according to one embodiment of the present invention.

14 is a state diagram showing that the color cells of the ileum in the conventional TV receiver have a vertical structure.

Fig. 15 is a state diagram showing that the color cells of the lobe of the stereoscopic TV receiver of the present invention are horizontal.

* Explanation of symbols for main parts of the drawings

8: stereoscopic optical information decomposing means 8 ': multi-slit grating

8 '': Photo plate grating 9: Optical system

10: subject 26: imaging surface

27: face plate 28: transparent conductive film

29: photoconductive film 42: panel glass

43: lenticular lens screen 44: recall with longitudinal color cells

45: recall with transverse color cells

The present invention relates to a three-dimensional image, a method, an apparatus for making a three-dimensional image for the purpose of realizing not as a screen representing a three-dimensional image in the picture, movie, OHP, TV and video screens It relates to various devices.

The film to be realized through a group of the present invention to realize a three-dimensional image is recorded three-dimensional optical information sufficient to represent a three-dimensional image, and when projecting such a film with a video imager can watch a three-dimensional movie. Also in the case of TV or video, the optical information emitted by the subject is converted into an electrical signal through the stereoscopic TV or stereoscopic video camera of the present invention, and then converted into stereoscopic image information through the stereoscopic TV receiver of the present invention. And this can be viewed in stereoscopic images.

Conventionally, in order to realize a stereoscopic image, two projectors equipped with a polarization filter polarized in the longitudinal and lateral directions are used and projected, and those are wearing glasses with a segregation filter, and the stereoscopic projection is viewed. The method is holography using a laser beam.

Holography, however, is a technique that uses wave interference to capture a stationary object, even if the surface of a stereoscopic image is limited to a limited range, it is impossible to capture a moving object, and even if it is a stationary object, there is no vibration at all. You can only take pictures.

In another conventional stereoscopic image implementation method, as shown in FIG. 1, a screen including a stereo camera or a camera equipped with a stereo photo adapter having two light incident portions at 7 cm intervals of left and right is composed of two screens. There is a method of viewing a stereo photograph through a stereo view and composing a stereoscopic image. However, the conventional method requires a plurality of photographic cameras, a polarization filter is required, a special light source such as a laser beam is used, or a strong constraint that photographing a moving object is impossible, but in the present invention, one camera is used. In addition to using the present invention, even a moving object can be freely implemented in a three-dimensional image by an easy method such as constructing a conventional planar image.

The present invention decomposes the optical information spoken by the subject into stereoscopic optical information of two components through the slits grating attached to the stereoscopic camera and records the stereoscopic optical information on the film, or prints the stereoscopic photo with the stereoscopic optical information again. The optical information emitted by the subject is decomposed into two-dimensional optical information through a slit grating attached to the stereoscopic movie camera and recorded on the positive film, or projected by the projector again to make a stereoscopic movie, or The optical information is decomposed into stereoscopic optical information of two components through a slit grating attached to a stereoscopic TV camera or a stereoscopic video camera, and then converted into an electrical signal and transmitted again to be reproduced on a stereoscopic screen through the stereoscopic TV receiver of each home. The invention consists of a group of inventions over a three-dimensional image.

In detail in the present invention, first, in the case of a stereoscopic image, optical information referred to by a subject is collimated through a camera lens, and the collimated optical information passes through a multi-slit grating installed behind the lens. It is decomposed into stereoscopic light information composed of two components, and the stereoscopic optical information decomposed into these two components is not overlapped on the negative film located on the upper surface installed at regular intervals behind the multi-slit grating. It is arranged to form a stereoscopic optical information on the negative film, and the image is formed on the film.

Second, in the case of stereoscopic films, the optical information emitted by the subject is collimated through the camera lens, and when this is again passed through the multi-slit grating, it is separated into two components of stereoscopic optical information, which is installed on the upper surface installed at regular intervals from the grating. On the located Yanghwa film, the images are recorded to record stereoscopic optical information that is not overlapped alternately. In this way, when a positive film on which stereoscopic optical information is recorded is projected on a Lenticular lens screen by a projector, a stereoscopic movie appears.

At this time, in the case of the first three-dimensional photograph or in the case of the second three-dimensional movie, the negative film or the positive film or the photograph with stereoscopic information looks like a film or photograph with conventional planar information, but in reality It is included.

Projecting a positive film with stereoscopic light information or placing a lenticular lens on a photo with stereoscopic light information will reveal the presence of stereoscopic images.

Third, in the case of realizing a stereoscopic image through a stereoscopic TV receiver, the faceplate is replaced by a multi-slit grating in an image tube of a TV camera or a video camera that is conventionally composed of a face plate, a transparent conductive film, and a photoconductive film. By installing a multi-slit grating between the faceplate and the transparent conductive film on the image tube structure of the camera, the light information emitted by the subject is transformed into an electric strength that can represent a three-dimensional image. Stereoscopic images can be converted to realize stereoscopic TV images.

The above-mentioned photo slitting grating of the multi-slit grating can also perform the function. In addition, methods of various apparatuses not yet mentioned, and stereoscopic cameras, stereoscopic TV cameras and stereoscopic video cameras, stereoscopic television receivers, and the like, which are used in the present invention to implement stereoscopic images, will be described in detail based on the embodiments described below. .

Herein, the contents of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a stereo photo adapter attached to an accessory to enable stereo photography in front of a photographing lens of a photo camera that is generally used. In this case, the stereo picture adapter is divided into left and right images incident on the lens by using four mirrors (3, 4, 5, 6). As shown in FIG. It is a device to take a picture. Stereo photography is also made by a stereo camera, a special camera that usually has two shooting lenses side by side approximately 7 cm apart so that you can take two photos from side to side with a single press of the shutter. When the stereo photograph thus produced is put into the stereo view 7 as shown in FIG. 3, the screen looks three-dimensional. However, although the stereoscopic image may be made by the conventional method as described above, in this case, not only the two left and right photographs are required, but also there is a disadvantage in that continuous stereoscopic images such as stereoscopic movies cannot be made.

4 and 5 show a grating which is importantly used in the present invention as the optical information decomposing means 8, where FIG. 4 is a multi-slit grating 8 ', which is completely transparent and the slits and slits Tsai is a completely opaque structure, and Fig. 5 is a photographic plate lattice (8 '') made by developing and fixing on a photographic plate, and when changing from a transparent place to an opaque place, the change of transparency occurs continuously and changes rapidly. Does not happen. Therefore, in the multi-slit grating 8 ', the amplitude of the light changes abruptly from above the slit to have a constant amplitude value. In the photo plate grating 8', the intensity of the light varies continuously from the minimum value to the maximum value, and the sine As a result of the change in the amplitude of light, as in a curve, more light is collected in a first-order diffraction wave than a higher-order diffraction wave.

6 shows the structure of a stereoscopic camera, which is an embodiment of the present invention. The film 12 is formed on the optical system 9, the stereoscopic optical information decomposing means 8, and the upper surface 11 positioned at a predetermined distance behind the stereoscopic optical information decomposing means. ) Is placed. When the picture is taken by the three-dimensional camera configured as described above, a film in which three-dimensional optical information is recorded can be obtained with only one screen. At this time, if you shoot continuously with a positive film and project it on a known lenticular lens screen using a conventional projector, you can see a phenomenal phenomenon that you can watch a stereoscopic movie. The cause of this phenomenon is as shown in Figs. This is due to the action of the grating on the same stereoscopic light information. The operation of the multi-slit grating 8 'will be described with reference to FIG. 6 with reference to FIG.

FIG. 7 illustrates that the optical information emitted by the subject is collimated through the optical system 9 and then converted into two types of stereoscopic optical information r and l which are decomposed into two types when the optical information is collimated and then passed through the multi-slit grating 8 '. It is shown that they are arranged so as not to alternately overlap the upper surface 11 spaced apart from the slits grating. At this time, if the positive film 12 is placed on the upper surface, the light information emitted by the subject is changed to stereoscopic light information r and l, which is decomposed into two components, so that the stereoscopic light information is recorded on the film 12. (r) and the fact that the stereoscopic optical information of two components having the directionality of the left (l) are arranged so that they do not overlap alternately has a significant meaning. That is, if optical information is arranged without alternating overlap, projecting it produces a flawless stereoscopic image without missing optical information, but if there is an overlap of two components, image confusion occurs at the overlapping portion. As a result of lack of conquest, clear stereoscopic images are not obtained. In particular, when the screen is enlarged to a large screen like a movie, even worse three-dimensional images are reproduced. In the case of the multi-slit grating, the stereoscopic optical information r and l of two components are arranged without being alternately overlapped because the presence of the opaque portion in the slits grating serves to prevent the overlap. Human eyes can distinguish the three-dimensional, because the two eyes are about 7cm apart can feel a wide angle. For this reason, the stereoscopic camera of the present invention for realizing a stereoscopic image if the diameter of the lens is 7cm or more When the three-dimensional image created by this lens is reflected back to our eyes, we can see a three-dimensional image adapted to the structure of the human eye. Therefore, when a lens such as a movie camera has a diameter of 7 cm or more and a grid is inserted into a stereoscopic camera, the stereoscopic image can be smoothly produced. However, in the case of a general camera, the lens diameter is usually 7 cm or less. In order to obtain a stereoscopic image that conforms to the function of the human eye, an improved stereo photography adapter 19 as shown in FIG. 8 should be used. This makes the distance between the two mirrors 13 and 14 toward the subject approximately 7 cm so that the two mirrors 15 and 16 opposite to each other form a constant angle α, which is the two mirrors facing the subject ( When the light beam reflected by 13 and 14 is reflected back to the inner two mirrors 15 and 16 and collimated by the lens 17 to reach the image plane, the angles of the two light paths are determined to coincide on the image plane. . The stereo photograph adapter 19 of the present invention is mounted on a general camera having a diameter of 7 cm or less, and a multi-slit grating which is a kind of stereoscopic photolysis means 8 in front of a predetermined distance of the upper surface of the camera. 8 ') is a stereo camera.

In a general camera equipped with such an improved stereo photography adapter 19, when a grating is installed in front of a certain distance of the upper surface, light information emitted by a subject is collimated by the lens through the stereo photography adapter and decomposed into two components through the grating again. The stereoscopic optical information is changed so that an image having stereoscopic optical information is recorded on the film existing on the upper surface, and the stereoscopic image in this case is adapted to the visual action of the person. Now, referring to FIG. 9, the stereoscopic image 22 according to the present invention capable of recording optical information emitted by a subject and the stereoscopic images 20 and 21 of the conventional stereo camera are compared. Conventionally, two screens 20 and 21 are required, but it can be seen that the stereoscopic picture according to the present invention is possible with only one screen 22.

9 is an exaggerated drawing for enlarging and enlarging both of them. Particularly, the photograph 22 in which the stereoscopic optical information is decomposed and recorded is several tens of intervals of two superimposed images, so it is represented in one screen. There is no sense in any way. Since the stereoscopic optical information is recorded on one screen by arranging two kinds of stereoscopic optical information on one screen 22 without being alternately overlapping, the positive film 23 according to the present invention as shown in FIG. ) Is projected on the lenticular lens screen 25 by successive photographing, it is possible to conveniently use the conventional projector 24 as it is to realize a three-dimensional image.

11, the structure of a stereoscopic TV camera or a stereoscopic video camera, which is one of the present inventions, will be described. It is surprising that in the structure of the conventional camera, if only a part of the imaging tube is changed, it becomes a stereoscopic camera capable of expressing stereoscopic information. The conventional imaging tube is composed of the face plate 27, the transparent conductive film 28, and the photoconductive film 29, but the imaging surface 26 in the stereoscopic TV camera or the stereoscopic video camera is formed of the stereoscopic optical information decomposing means 8. It is composed of a multi-slit grating 8 ', a transparent conductive film 28, and a photoconductive film 29, which is a kind, and replaces the face plate 27 with a multi-slit grating in the structure of a conventional image tube. Equivalent to replacing (27) with a multi-slit grating. In this case, when the multi-slit grating is thin, the face plate 27 may be positioned in front of the multi-slit grating 8 '. Here, of course, even if the photo plate grating 8 '' is used instead of the multi-slit grating 8 ', there is no significant change in function, and the image pickup surface 26 is used to detect the concentration of light emitted from a three-dimensional image such as a landscape or a person in a camera. It converts the signal into an electric strong signal with stereoscopic light information. A stereo TV receiver is required to reproduce the electrical signal having the converted stereoscopic optical information into stereoscopic image information. Now, a stereoscopic TV receiver which is an embodiment of the present invention will be described. By the way, the fact that these can be switched to the stereoscopic TV receiver of the present invention by changing the conventional TV receiver only a little will have a practical significance.

In FIG. 12, the structure of the three-dimensional stereoscopic television receiver is shown. The optical signals of three CRTs of the red (R) green (G) blue (B) are optically transmitted through the half mirrors (30, 31). On a known Trineskov TV receiver that can be synthesized and viewed, the optically synthesized image is enlarged again through the optical system 35, and the enlarged image can be viewed through the lenticular lens screen 36. The effect is that the electrical signal transmitted through the stereoscopic TV camera or stereoscopic video camera of the present invention can be converted into stereoscopic images for viewing.

FIG. 13 shows the structure of a stereoscopic reflective TV receiver, and receives an electrical signal having a stereoscopic image transmitted from the stereoscopic TV camera or the stereoscopic video camera of the present invention and again through three CRTs 37, 38, and 39. The stereoscopic image information of red cyan, which is changed into image information having stereoscopic optical information and enlarged through the optical system, is reflected by the half mirror 40, and the stereoscopic image enlarged on the lenticular lens screen on the front of the half mirror is matched. When the image having the formed stereoscopic information is observed through a lenticular lens screen, it can be viewed as a stereoscopic image.

In addition, the stereoscopic liquid crystal TV receiver which is one of the present invention is provided with a lenticular lens screen in front of a known liquid crystal TV receiver, and the stereoscopic liquid crystal TV receiver configured as described above can decompose light information emitted by a subject into a plurality of stereoscopic optical information components. Through the image pickup tube having a means capable of doing so, it is possible to reproduce what has been transmitted as an electrical signal having a three-dimensional signal back to a three-dimensional image.

The stereoscopic TV receiver of the present invention will be described with reference to FIGS. 14 and 15 for a stereoscopic TV receiver which is one of the present inventions capable of reproducing a stereoscopic image using a color TV receiver which is currently widely used. The panel glass 42 formed at a constant curvature of the lens is replaced with a lenticular lens screen 43 in which the direction of the lenticular lens is formed at the same curvature. The three-dimensional TV receiver of the present invention should be composed of three color cells of red green and blue in a transverse direction so that the color cells are constituted in the longitudinal direction and form one burner 44 to form one burner 45. The stereoscopic TV receiver configured as described above can receive a signal from the stereoscopic TV camera or stereoscopic video camera of the present invention and reproduce the continuous stereoscopic image again. It is not difficult for a person skilled in the art to make various changes of the present invention easy to carry out, and thus various changes within the scope of the present invention belong to the spirit and scope of the following claims. The present invention consists of a group of inventions for implementing stereoscopic images, all of which can be changed from planar images to stereoscopic images across all photographic, film and TV industries by making simple changes to existing devices. Makes it possible.

Claims (28)

Or an optical information decomposing means 8, a transparent conductive film 28, and a photoconductive film 29, which enable conversion of optical information collimated through the optical system 9 into an electrical signal having stereoscopic image information. Or a face plate, an optical information decomposing means, a transparent conductive film, and a photoconductive film. The optical information collimated through the optical system is composed of a decomposition means for decomposing the stereoscopic information into a plurality of components, a transparent conductive film and a photoconductive film, or a face plate and optical information decomposing means, and a transparent conductive film and a photoconductive film. A stereoscopic TV camera characterized by providing an imaging surface (26) so as to change the collimated optical information into an electrical signal having stereoscopic image information. The stereoscopic TV camera according to claim 2, wherein the disassembly means (8) is a lattice. 4. A stereoscopic TV camera according to claim 3, wherein the grating is a multi-slit grating (8 '). 4. A stereoscopic TV camera according to claim 3, wherein the grating is a photographic plate grating (8 ''). It consists of a decomposing means 8 and a transparent conductive film 28 and a photoconductive film 29 or the face plate 27 which decomposes the optical information collimated through the optical system into three-dimensional optical information. The imaging surface 26 composed of the means 8, the transparent conductive film 28, and the photoconductive film 29 can be provided to convert the collimated optical information into an electrical signal having stereoscopic image information. Stereoscopic video camera. 7. Stereoscopic video camera according to claim 6, characterized in that the decomposing means (8) is a grating. 8. Stereoscopic video camera according to claim 7, characterized in that the grating is a multi-slit grating (8 '). 8. A stereoscopic TV camera according to claim 7, wherein the grating is a photographic plate grating (8 ″). Decomposition means (8) for decomposing the collimated optical information back into three-dimensional optical information components by placing the optical information emitted by the subject behind the collimated optical system and the optical system, and an upper surface (11) Stereoscopic cinematograph which consists of film installed at) and is able to record images with stereoscopic light information continuously. The stereoscopic cinematograph according to claim 10, wherein the decomposition means (8) is a lattice. 12. A stereoscopic cinematograph according to claim 11, wherein the grating is a multi-slit grating (8 '). 12. A stereoscopic cinematograph according to claim 11, wherein the grating is a photographic plate grating (8 ''). The distance between the two mirrors 13 and 14 facing the subject is spaced at a predetermined distance, and the two inner mirrors 15 and 16 facing the two mirrors form an angle α, but the two mirrors facing the subject The light reflected from the mirrors 13 and 14 is again reflected by the inner two mirrors 15 and 16 having a constant angle α and collimated by the optical system 17 to reach the upper surface. Stereo photo adapter 19 is made so that the light path is matched to one place from the top surface, so that one picture can be taken in one frame of the film located on the top surface. It is composed of a decomposing means 8 and a transparent conductive film 29 and a photoconductive film 29 which decompose to decompose the light information emitted by the subject into various kinds of three-dimensional light components, or the face plate and the decomposing means 8 and After the stereoscopic TV camera or stereoscopic video camera having the imaging surface 26 composed of the transparent conductive film 28 and the photoconductive film 29 converts the optical information emitted by the subject into a signal having stereoscopic image information, And realizing a stereoscopic image by receiving an electrical signal from the image information using a stereoscopic television receiver having a screen capable of reproducing a stereoscopic image. 16. The stereoscopic image realization method according to claim 15, wherein the decomposition means (8) is a lattice. 17. The method according to claim 16, wherein the grating is a multi-slit grating (8 '). 17. The method according to claim 16, wherein the grating is a photographic dry plate grating (8 ''). The stereoscopic image realization method according to any one of claims 15 to 18, wherein the screen capable of reproducing a stereoscopic image is a lenticular lens screen. Magnified image from a known Krinesko TV system configured to optically synthesize color signals by using two half mirrors 30 and 31 and three cyan tubes 32, 33 and 34. Stereoscopic camera or stereoscopic camera having an imager comprising a means for decomposing the stereoscopic optical information emitted by the subject into stereoscopic optical information of various components by providing an optical system 35 and a lenticular lens screen 36 that can be made A trinesco-type stereoscopic television receiver, which enables an electrical signal having stereoscopic image information captured by a video camera to be reproduced in stereoscopic image again. A three-dimensional TV camera or a three-dimensional video camera made by a three-dimensional TV camera or a stereoscopic video camera having a means for decomposing light information emitted from a subject into three-dimensional optical information of various components, and receives three signals of red green and blue The CRT (37, 38, 39) is converted back to the image information having stereoscopic optical information, and the stereoscopic image information enlarged through the optical system is reflected by the half mirror 40, the lenticular lens screen on the front half mirror A reflection type stereoscopic television receiver which allows an image having stereoscopic information enlarged in (41) to be matched and formed to be imaged, so that the image having the stereoscopic information thus formed can be viewed as a stereoscopic image through a lenticular lens screen (41). A liquid crystal TV receiver provided with a lenticular lens screen in a configuration of a known liquid crystal color TV receiver to receive an electrical signal having a stereoscopic image signal and to reproduce it in a stereoscopic image. Three color cells constituted in the horizontal direction form one pixel 45, and a lenticular lens screen 43 having the same curvature as the conventional penal glass 42 formed with a constant curvature is formed to be three-dimensional. A stereoscopic television receiver capable of reproducing a stereoscopic image of an image transmitted by an electrical signal having image information. In order to convert an electrical signal having stereoscopic image information made by a stereoscopic TV camera or a stereoscopic video camera having an imaging device having a means for decomposing light information emitted from a subject into stereoscopic optical information of various components, into a stereoscopic image. TV set with a lenticular lens screen. A stereoscopic TV camera or stereoscopic video camera with an imager that includes a decomposition unit that can decompose light information emitted from a subject into stereoscopic optical information of various components as a component converts light information emitted by a subject into an electrical signal. Video tapes recorded directly or through a medium. A stereoscopic TV camera or a stereoscopic video camera having an imager comprising as an element a stereoscopic optical information decomposing means comprising a grating, which directly or indirectly converts optical information emitted by a subject into electrical signals. Recorded video tape. 27. The method according to claim 26, wherein a stereoscopic TV camera or stereoscopic video camera having an imager comprising as an element that the grating is a multi-slit grating converts optical information emitted by a subject into electrical signals directly or through a medium. Recorded video tape. 27. The stereoscopic TV camera or stereoscopic video camera of claim 26, wherein the grating is a photographic plate lattice, which records the conversion of the optical information emitted by the subject into an electrical signal, directly or through a medium. video tape.