JPH08508369A - Method and apparatus for forming stereoscopic image - Google Patents

Abstract

(57) Abstract: A method and apparatus for forming a stereoscopic image, comprising the step of displaying on a screen an image that is formed around a common center and that is divided and separated and that includes two or more spaced angular fields of view. Is. This divided and separated image is visible through grid means having a size and shape that substantially corresponds to the size of the divided portion of the image. From the screen, the image segment obtained to the left of the common center of the image is substantially visible to the observer's left eye, while the image segment obtained to the right of the common center of the image is substantially visible to the observer. A grid is placed at a distance visible to the right of. The relationship of the left and right part of the image to the grid is maintained by vibrating the grid with respect to the part of the image appearing on the screen.

Description

Description: Method and apparatus for forming stereoscopic images Field of the invention The present invention relates to methods and apparatus used in producing stereoscopic images. Conventional technology To date, stereoscopic images have basically been created by means of presenting different faces of the object to each of the eyes, and usually the image can be viewed with filters, polarizing and / or vibrating viewers or glasses. , Filtered, polarized and vibrating images. There are also lenticular arrays, stationary or dynamic dual image strips and visual slot mechanisms that seek to achieve similar effects without the use of such viewers or glasses. “Stereoscopic” is a word that has been commonly used for many years. The meaning of this term has been expanded from its first use to include a three-dimensional view that is actually visible and to include a wide range of depth-enhanced images. There are two broad and general categories of applicable methods, devices and effects. One of these categories relates to images containing a single angle of view of an object. The other category relates to images that simultaneously contain multiple angular fields of view of substantially the same objective. Methods and devices that allow to present two or more different angular fields of view of substantially the same objective are also referred to as three-dimensional. Generally, these configurations are 57.15 to 63.5 mm (2-1 / 4 to 2-1 mm) to a common center by the method and means of separating the left image to the left eye and the right image to the right eye. We present two spaced angular fields of view obtained at a spaced distance of 1/2 inch). Optical systems with separated left and right images include in their sophistication eyeglasses ranging from simple filtered eyeglasses or polarized eyeglasses to liquid crystal visors synchronized to screen signals. Includes viewers and visors. Other techniques for making the left and right angular fields visible only to the corresponding eyes include lenses for segmenting the image, especially lenticular arrays, and separate left and right still image strip mechanisms. In addition, the hologram forms a stereoscopic image containing multiple angular fields of view. Furthermore, there are many combinations of these various systems. However, in spite of many methods and techniques for increasing the depth of an image and forming an image including a visible three-dimensional area, all of the techniques are extremely limited in their application examples, and their commercial use is limited. There is a limit to the practical and practical success. In particular, they are commonly used, for example, in movies, video computer display units, television screens and various monitors that are routinely used for medical diagnostic, entertainment and military surveillance purposes. There are no known systems suitable for application in most video systems. It is an object of at least one aspect of the present invention to provide a method and means to date that solves or minimizes the problems and drawbacks associated with known methods and means. Other objects of the present invention will be apparent from the following description. Disclosure of the invention According to one aspect of the invention, there is provided a method of forming a stereoscopic image, the method comprising: displaying a divided and separated image on a screen including two or more angular fields of view spaced about a common center. Including a segmented portion of the image visible through grid means sized and shaped substantially corresponding to the dimension of the segmented portion of the image, the grid being located at a distance from the screen, The image segment obtained to the left of the center of the common image is substantially visible to the observer's left eye through the grid, while the image segment obtained to the right of the center of the common image is through the grid. It is substantially visible to the observer's right eye and its construction is such that the grid is substantially in sync with the segment of the image appearing on the screen and the observer's eye. To And by vibrating at a rate such as to form a complete three-dimensional image in a coherent, the method being characterized in that a structure in which the relationship of the left portion and right portion of the image corresponding to the grid is maintained is provided. According to yet another aspect of the invention, a method of forming a stereoscopic image comprising displaying on a screen surface an image comprising two or more angular fields of view spaced about a common center, the method comprising: The angular field of view is divided and separated such that the divided and separated angular field of view of the image is visible through each portion of the grid having a size and shape that substantially corresponds to the size of the divided portion of the image. However, from the screen, the split portion of the image obtained to the left of the center of the common image is substantially visible to the left eye of the observer through the portion of the grid, while to the right of the center of the common image. The divided parts of the image are arranged at a distance substantially visible to the observer's right eye through the grid part, and when the image is displayed on the screen, the part of the grid is coherent and completely stereoscopic. By vibrating in synchronism with the display of the divided parts of the image at the speed of forming the, so that the relationship between the left and right divided parts of the image with respect to the grid part is maintained. Provided. According to yet another feature of the invention, a method of forming a stereoscopic image comprising the step of displaying on a screen surface an image that includes two or more angular fields of view about a common center. The fields of view are divided and separated, the divided and separated angular fields of view being viewed through a grid portion of a size and shape that substantially corresponds to the size of the divided portions of the image, the grid being From the screen, the image split obtained to the left of the center of the common image is substantially visible to the left eye of the observer through the portion of the grid, while the split image obtained to the right of the center of the common image. Are placed at a distance that is substantially visible to the observer's right eye through the grid portion, and when the image is displayed on the screen, the grid portion forms a coherent and complete stereoscopic image. By vibrating at a speed in synchronism with the display of the image portion, the relationship of the left and right portions of the image with respect to the grid portion is maintained, the grid portion being between the viewer's eye and the screen. A method is provided that is substantially invisible as a transparent window portion. According to yet another feature of the invention, a device for forming a stereoscopic image, the means for displaying on a screen surface an image comprising two or more adjacent angular fields spaced apart about a common center; Grid means provided in front of the screen, wherein the angular field of view is divided and separated, and the divided and separated angular field of view of the image substantially corresponds to the size of the divided portion of the image and As viewed through a portion of the grid having a shape, the grid means is spaced from the screen by a distance, and the resulting divided portion of the image to the left of the center of the common image is through the portion of the grid. While substantially visible to the observer's left eye, the resulting image segmentation to the right of the center of the common image makes the image substantially visible to the observer's right eye through the grid portion. When displayed on the clean side, the grid means and the portion of the grid vibrate in synchronism with the display of the divided portion of the image at a speed at which a correlative and complete stereoscopic image is formed. And a right side portion is maintained. Brief description of the accompanying drawings The invention will now be described, by way of example only, with reference to the accompanying drawings. FIG. 1 is a schematic plan view of one embodiment of the present invention, and FIG. 2 is a schematic plan view of yet another embodiment of the present invention. Detailed description of preferred embodiments of the invention and methods of practicing the embodiments. As mentioned above, the present invention provides a method and apparatus that can be displayed on a screen such that the image is viewed through a vibrating grid so that the image appears in full three dimensions. . The present invention combines two findings. Each of these findings extends the contents of the previous findings regarding the previous invention, and these new findings enable improvement of such conventional inventions. When these two improvements are combined with each other, a practical and commercially valuable stereoscopic image is formed for the many purposes for which stereoscopic images are desired to achieve. The first improvement relates to presenting a stereoscopic image on the screen. To date, more than one angular field of view captured around a common center of the same objective is provided on the screen, all elements of each image are perfectly aligned, so that a large number of adjacent angular fields are It is considered impossible to make it appear as a single coherent stereoscopic image, except at the outer edges of the image. There are two possible reasons to support this. First, it is due to the general assumption that for humans, the stereoscopic image is mainly due to the action of the interstitial distance of the human eye. Secondly, explaining human vision in terms of a geometrical perspective is of course that one eye must see any identical point on the screen at a different position than the other eye. This is because it demonstrates that it cannot happen. In the first case, there is a standard value in which the distance between the pupils of different human eyes is optimized, averaged, or set as substantially suitable for anyone to see stereoscopic images. do not do. Despite this, for the purpose of creating a stereoscopic image, 57. 15 to 63. It seems widely believed that a separation of 5 mm (2-1 / 4 to 2-1 / 2 inches) is required. Images obtained with this degree of separation around a common center cannot be rendered on the screen to be seen by the naked eye in perfect stereoscopic alignment. Furthermore, presenting human observations in a three-dimensional geometric form means that each eye must see the same point at different positions on the screen, so except for the center, there is a common Both naked eyes cannot see any point of two or more adjacent images taken from different angles around the center at the same position on the screen, resulting in a registered stereoscopic image. I was told that I could not. For these two reasons, over the years, two or more images of substantially identical objectives obtained adjacently are aligned on one screen in a way that simulates the field of view of the human eye. It is therefore not possible to compare two parts of the two images that appear on the screen, with each image being seen in each eye completely separated. It has been believed that you can see an image in three dimensions only when you cannot do it. Throughout this century, the perception of a human stereoscopic image is a distance equal to the width of the pupil of the eye, or about 63. It is widely understood to be separate, separate observations of two different angular fields of view of an object when viewed from positions separated by 5 mm (about 2-1 / 2 inches). Therefore, based on this understanding, the formation of stereoscopic images is mainly done by eyeglasses that identify the images. This method of applying a suitable viewer to form a stereoscopic image appears to hinder the widespread use of such images, as the general public does not like to use this type of optical instrument. Other solutions, such as providing a tensic array on the screen, have the additional disadvantage of narrowing the viewing area, as the eyes need to be centered in the focus of the lens. Yet other solutions, such as holography, are costly. A main feature of the present invention is that the basic recognition that two or more adjacent angular fields of view cannot be stereoscopically aligned on the screen for viewing with the naked eye is a fundamental error. The knowledge makes it possible to develop an improved technique that solves the inconvenience of having to hang up the viewer when viewing a stereoscopic image, or to use a technique with equal or greater improperness. In 1923, Demetre Daponte centered around 63. Two adjacent angular fields of view, spaced 5 mm (about 2-1 / 2 inches) apart, can be partially stereoscopically aligned on the screen by alternately darkening each of the images. I disclosed what I can do. The Daponte invention that discloses this finding is called a "pulsometor." The pulse meter consists of two discs whose transparency is progressive from perfect to zero, the discs rotating in opposite directions so that the angular field projected through these discs is Among them, it becomes darker or brighter, contrary to the other image. In Daponte's findings and invention, only a portion of the two images is stereoscopically matched, the proportion of the images thus matched is small, at most 1/4 of the horizontal length of the images. Occupy nothing. One of the findings of the present invention is that an image consisting of two or more adjacent angular fields of view is stereoscopically displayed on the screen, provided that the angle between the fields of view and the foreground and background of the objective are small enough. It can be perfectly matched. In practice, the separation angle and the distance between the foreground and the background of the objective depend on the distance of the center of the objective, the total depth of field, the type of lens used, the focus, the vertical and horizontal alignment of the images. Decided. Regardless of all these variables, the angle is always 12. For objectives closer than 2 m (40 ft), it is extremely small and it is difficult to distinguish the difference between the two images. Despite the fact that the centers of the images are physically separated, a high performance resolving device is essential. As a guide, this angular field of view is at least 12. 0 for objectives within 2 meters (40 feet). 25 (1/4) ° or less. The significance of this finding, combined with another finding and another refinement of other inventions, is that this extremely small displacement angle can be applied in a flexible manner that allows it to be applied to most conventional imaging devices. Is the point that can be increased. Basically, this is achieved by applying a system with a variable separation distance to two different images and varying the degree of separation as needed. Like the other features of stereoscopic images, for more than a century, the left and right angular fields of view of one objective are divided and the strips are placed on flat surfaces separated by slats or similar dividers. It has been known that a three-dimensional image can be formed thereby. At this time, the observer positions his eyes as follows. That is, while the left eye sees the left image strip while preventing the slats from seeing the right image strip with the left eye and the right eye seeing the right image strip with the right eye seeing the slats seeing the left image strip with the right eye. Set the position to This known arrangement forms a stereoscopic combined image, but is always limited by the deterioration of the overall result due to the slats that separate the images. Another solution was proposed by Francois Savoye, who made the "cyclostereoscope" and filed a patent for it in the early 1950s. The cyclostereoscope comprises a circular grid that rotates about the screen through which adjacent left and right angular field of view images are projected onto the screen. The idea proposed by Savoie intended to shift the image-separating visor worn around the eyes of the observer into a configuration of similar function acting around the screen. Savoie provides a grid that alternately interferes with the observation of each eye of different combinations of angular field strips, at such a rate that memory and vision perceive the combined strips as two stereoscopic two-dimensional views. The aim is to rotate the entire grid so that all the splits are exposed continuously. The savoy achieves a segmented seating configuration of partial and defined areas that optimizes the partial stereoscopic image and confines the observer to areas where viewing of two overlapping images is minimal. An optical system for observing an image by an improved grid is a characteristic feature of the present invention, which solves a problem associated with a region caused by Savoie's idea and eliminates the need for a rotating circular grid. To do. A second finding of the present invention is that images containing two or more adjacent angular fields of view obtained around a common center of substantially the same objective are different images, and thus the corresponding eye separation distance increases. By expanding the divergence angle in accordance with the above, it is possible to match as a completely correlative stereoscopic image except for the outer edge portion. In practice, it is necessary to successively divide and separate the images, so that an equal number of equally sized and equally spaced images appear on the screen and can be seen through the vertical grid, thus The image seen by the left eye of the image segment on the left side of the center of the objective is in a way that it is more excluded as the divergence angle between the images increases, from the image seen by the right eye of the image segment on the right side of the common center. To separate. As a guide, when applying this optical system to two or adjacent angular fields obtained around the common center of one objective, the center of each different image will be any two adjacent arbitrary fields. About 6. Horizontal separation in the range of 35 to 127 mm (about 1/4 to 5 inches). For extreme close-up images, or images at infinity and beyond, these positions may be closer or further away, accordingly. To maintain this relationship in such a way that it overcomes the limits of a rotating circular grid, i.e. the inertial forces of an oscillating mechanical grid, a grid formed by a liquid crystal display synchronized with image segmentation is used in this grid system. Can be installed in In order to eliminate the occurrence of grid lines that form a perfect stereoscopic image and degrade the image, the divided and separated images with increased separation by the grid are both vibrated in a synchronized state, for example, Its function is maintained at a speed of 50 hertz or more, where the divided parts merge to form a completely correlative stereoscopic image, and the grid lines vibrate at an invisible speed. . This combination allows the area to be free-spaced by any angle perceivable by humans by widening or narrowing the grid lines without limiting inertia or causing incompatibility with most conventional devices. An image is formed. To date, stereoscopic images have been formed and observed in what can be termed "two separate images". This has been done using eyeglasses, known means and devices and the like. However, a stereoscopic image of the "two separate images" type, which consists of separate right and left images and sequentially blocks these images, basically creates a visual realism that humans actually experience. It cannot be realized. In other words, the eye normally transmits images to the brain. Such stereoscopic images are perceived as images and are therefore unnatural. Furthermore, in the case of such known forms of stereoscopic images, for example, the viewing angle of the image is limited, incompatibility with conventional devices, transmission and broadcasting difficulties, image quality is substandard, Fatigue, lack of commercial value and impracticality, and other drawbacks such as those associated with many people who have impaired vision. As one background of the present invention, and for the purposes of this specification and for the specific purposes herein, it is generally believed that the eye can often be perceived as being a dynamic sensor. . The human eye generally sees the horizontal and vertical planes at substantially the same time, and the depth of field and its focus are constantly changing. This basically dynamic perception, combined with memory, preserves the impression of an infinitely changing image of everything we see. It is generally believed that memory is not always given a single left or right distinct image, but always a different partial and contiguous image over a range. These changing partial and adjacent images are combined in human memory, the brain, to have a certain image depth and become a single coherent image that manifests itself stereoscopically. Also, the human eye is generally considered to perform scanning rapidly and continuously. As mentioned above, the human eye does not focus on one point in succession to produce one right and left image. The field of view of the human eye is constantly changing, and both eyes are constantly moving over a changing point with one eye crossing the field of view of the other eye. Moreover, humans are constantly moving their heads, and the eyeballs often move within their eye cavity. Therefore, even if two different changing images or photographs (one on the right side and one on the left side) are transmitted from far away from the human mind, that is, the brain, the one that the brain receives is continuous. It is a partial, partial, and adjacent divided and separated image. To date, optical instruments that utilize the basic principle of forming two separate images to simulate stereoscopic recognition are believed to be constrained by essential limitations. Due to such limitations, such optical systems and means can only present stereoscopic images in horizontal planes, each with a constant depth and focal length. From the above discussion, it is believed that these images are neither realistic nor perceived as being realistic. In fact, such a known optical system cannot reproduce a realistic stereoscopic image. One basic feature of the invention is that it is commercially viable by eliminating the need to wear eyeglasses to divide the image or to use intermediate optics between the image and the observer. , Providing a method of forming a stereoscopic image. The present invention, in its preferred form, makes it possible to form a wide-angle stereoscopic image with little modification or addition to the prior art, which is performed as follows. Be seen. That is, a number of adjacent angular fields of view, each of which is displayed partially or progressively across the screen, as a separate image portion, or as a combination of separate image portions, in apparent perfect alignment. It is housed around a common center in the image and further, at a sufficient velocity, as a constant field-of-view displacement between the components of a constant, single correlative and perfect stereo image of the image on the screen. It is done by varying to collectively reveal continuously varying spatial displacements between the parts. The invention also ensures that the angles between multiple images around the common center of each image are: That is, a rapidly changing segment of the image containing that angle displays an apparent constant visual displacement between the image components, while the components in the image appear in alignment. The angle should be such as to prevent or minimize the appearance of multiple or multiple images in any portion of the image. The term "form" shall mean to be captured, formed or configured to be immediately displayed on a screen, immediately transmitted for display, or immediately broadcast for display. The term forming is also meant to be stored, captured, formed or constructed for later display, transmission, broadcast, or projection. The device used to capture this image shall be a camera, cinema camera, video camera, hologram camera device, or display, separate, or split so that the captured image appears stereoscopically on the screen. Any device capable of obtaining an image containing a number of adjacent angular fields about a common center in a manner that allows Dividing a number of adjacent angular fields around a common center is done when the image is captured in an optical system such as a camera, or during or as part of the processing of the film, of the storage portion. It can be done at any time prior to display, such as input or search, edit, and during slides, film prints or videotapes for sale, during transmission or broadcast, or during reception. In addition, appropriately segmented images can be formed during the formation of images such as computer images or graphics, or during the production of cartoons. The term "image" means a slide, an image contained in a frame of film, an image on videotape, an x-ray image, or an actual object, to reproduce a symbol, or as a computer image or cartoon. To represent an object or symbol is meant to form any sharply configurable image that can be recorded, posted, or generated. Further, the term image is intended to include each image sequence or one image sequence showing the same image. The term display shall mean to visibly project, display, project or form an image. The term screen shall mean any surface on which an image may be visibly displayed and displayed, projected or formed, or any volume on which the image may appear. The term alignment means that in size, shape, vertical and horizontal position each image is apparently exactly registered on top of the other images, and multiple images appear different only in depth or dimensionality. It is meant to appear progressively across the screen, of course, in the same form, not to appear as more than one image, or as two or more parts of any image. In practice, the dimensions of these splits will vary depending on the medium used for capture or vision. The present invention is a realistic and commercially viable stereoscopic image that appears on the screen surface one after the other or at substantially the same time and the image is recorded in the manner as shown on the screen. A method and apparatus for doing so are provided. This image can be recorded on any suitable medium such as film, tape, slides, holograms and the like. In one form of the invention, the image is then recorded on a medium as a slide or photograph, as in a movie, or as can be shown on a television, video device, or the like. In yet another aspect of the invention, the means for recording the image, such as one or more cameras, is adapted to receive the image and display the recorded image on the screen surface of the camera or cameras themselves. A camera or cameras coupled to suitable transmission means capable of being transmitted to such means as a television device capable of For example, it is like a television camera used in an outdoor broadcasting device for television news, sports events and the like. These are merely examples. Thus, the present invention relates to a method and apparatus for recording an image for viewing the image on a screen surface thereafter, or substantially simultaneously. The present invention does not relate to a method and a device enabling the pre-recorded image to be viewed on the screen as it appears stereoscopically. The method and apparatus of the present invention comprises providing a lens, or lens system, that allows to record or capture two or more similarly sized angular fields of substantially contiguousness of the image or object to be recorded. I need. In general, it is better to be able to capture or record a large number of smaller angle images rather than a small number of large angle images. However, it should be understood that in the present invention it is necessary to record two or more different angular fields of view. Furthermore, it is a further feature of the present invention that the image is recorded for subsequent or simultaneous observation, and always only a partial and adjacent portion of each angular field is captured or recorded. As can be seen, this means that when displaying an image, at any instant, at no instant a large number of angular fields of view are visible, and for the eyes to merge parts of the image at different angles, It only appears as a series of subdivisions at a certain speed, which means that when viewed, the recorded image has the depth of the image and is perceived by the eye as a stereoscopic image. That is, it becomes an image as the normal function or function of the human eye. In one form of the invention, partial and adjacent angular fields of view are recorded in a discontinuous manner by using the apparatus and method of the invention. The recording of such a discontinuous adjacent and partial angular field according to the invention makes it possible to subsequently display such a discontinuous adjacent and partial angular field of view, and With the depth of the image, it becomes possible for the human eye to see the image as a substantially stereoscopic image. The invention provides that means are provided in connection with a lens or camera, or associated with the recording of multiple angular fields of view, so that the images are recorded in partial, adjacent and spaced-apart states. To do. To this end, the present invention provides a grid, grid device, separator, angular field obstruction device, light or signal blocking mechanism, switch or processing means as one component or feature that is essential for image recording. Required, so that the recorded image is recorded partially and from two or more spaced adjacent angular fields of view. The present invention describes images recorded from two spaced angular fields of view, one to the left and one to the right. However, it should be understood that this is merely an example, and the image may be recorded from more than one angular field of view. The means used to record a number of partial and adjacent angular fields of view can be separate from the recording means, such as a camera, or integrated into the camera. While the various aspects of the present invention are described by way of example only with reference to the accompanying drawings, it should be understood that these are merely examples. For example, the camera may be incorporated into suitable means to make the image partial and contiguous, such means may be incorporated into the camera but arranged so that it does not interfere with the shutter or scanning function. It may be in the form of a jamming device such as a device. Furthermore, such mechanisms should be timed to operate so as to eliminate lines, flashes, spots or other optical noise, distortion or image degradation as much as possible. However, in one form, it is contemplated that the camera may be an electronic camera capable of recording partial and adjacent angular fields of view of one or more objects being recorded. . Such cameras can have multiple spaced lenses, or alternatively, multiple such cameras can be utilized, after which the recorded images are mixed and processed. In an embodiment of the invention where a blocking device or grid device is provided inside the camera, such device may be any device capable of reliably blocking the capture or recording of an image in front of, inside or behind the lens or through the lens. The images provided in position, recorded on the medium or recorded by the camera may be only partial and adjacent images. When such a device is incorporated into a camera, the grid or blocking device should be located adjacent to the film surface and as close as possible to the film surface behind the lens and should be synchronized with the camera shutter. Alternatively, it may be substituted for the shutter or incorporated in the film gate. In various forms of the invention where multiple angular fields of view are captured and recorded by film or electronically, the multiple recorded angular fields of view are known mechanical means, electro-optical means, electrical means. Means, or by means such as, for example, a split mixer or the like, can be subsequently modified to include partial and adjacent angular fields of view. It is conceivable that media such as film or tape with a programmed grid or pattern applied on it or with voids in it could be used in the camera to simplify the recording function. In yet another form of the invention, it is contemplated that a display device that imparts an image blocking pattern may be used to mix images at multiple angles. For example, it is possible to use a liquid crystal display that traverses the display at the required speed and provides lines or voids that divide the image, forming a dynamic optical grid. The present invention is described further with respect to its preferred embodiments and with reference to the accompanying drawings (as described below). In a preferred form of the invention, the image is displayed on the screen as a result of being generated or created by the computer on the screen, or on the screen via a protection means. In the accompanying drawings, by way of example only, images are shown as viewed through grid means (further described below). The screen 1 is shown as having a screen surface 2 and the grid means are provided substantially in front of said screen surface 2 and at a position substantially spaced from said screen surface, said grid The means 3 are preferably in the form of a liquid crystal display screen which, in operation, produces a plurality of vibrating grids through which an image can be seen on the screen. Other forms of grid can be used if desired. For example, a physical grid with multiple slots or openings 4 of different depths that extend across the front of the screen. However, the grid means has a plurality of grid portions or openings and the grid means 3 is in the form of a liquid crystal display screen or other suitable electrical or chemo-optical mechanism for physically separating the images. Is desirable. This liquid crystal display screen is preferably constructed so that the grid 3 vibrates so as to meet the requirements of the invention. In another form of the invention, the grid means can be moved or vibrated by an additional mechanism or power supply means. By way of example only and with reference to FIG. 1 of the accompanying drawings, the grid 3 is shown in a position spaced forward from the screen surface 2 and in front of the screen 1 in the housing or cover 9. One form of the invention is shown integrated (generally substantially in the figure), the screen may be a screen of a television device, a cinema screen or the like. In yet another form of the invention, shown by way of example only in FIG. 2 of the accompanying drawings, it is possible to provide a plurality of grid means 3 spaced apart to form passage portions or slots 4 therebetween. When the grid means vibrates or moves, the image on the screen surface 2 appears stereoscopic. For other forms of the invention, the screen 1 and the spaced grid means 3 can be arranged or housed in the housing 9 in a substantially integral manner. Alternatively, they can be separated from each other. It will be appreciated that at least the grid means 3 can be, for example, crystalline, liquid crystal or an electro-optical material that performs a similar function. When used to form a suitable grid or surface, the material should be: For example, dirhenium arsenide, lithium niobate, potassium dihydrogen phosphate, inorganic compounds such as barium borate, organic compounds such as methyl nitroaniline and nitroaminostilbene, amino groups, methoxy groups, Materials from electron donors such as hydroxyl groups, materials from electron acceptors such as nitro, cyanide compounds, esters and nitroso groups, polymers, polyenes, polydiacetogrene, or other materials with electro-optical properties. , The property of changing the frequency of light, a central non-contrast molecular structure, or a crystal structure in which an anion is completely replaced by an electron, such as an alkaloid or a complex compound such as potassium hexamethyl hexacyclane sodium It is the body. This electro-optical material can be constructed as follows. That is, a single piece or multiple pieces such as blocks, slabs or chips, large and small pieces of any shape, films, thin films, solutions, suspensions or laminated between other materials such as glass. , Or a mixture with other electron-optical components, or a mixture with other materials that are components other than electron-optical components. For example, if the electro-optical material of the grid is constructed as lines, rods, strips, slats, panels or braids, these can be in rows, partial rows, staggered rows, parallel, parallel rows, horizontal orientation. It can be positioned in rows, or vertically (or both), or in cross rows. Further, they may be placed at different locations in the display with different lengths and dimensions. As mentioned above, these are merely examples, and grids, such as grids of any suitable material, formed with slots and capable of vibrating in a suitable manner are compatible with the conditions of the present invention. Can be used as As can be appreciated, in operation, the present invention provides a stereoscopic image (formed, formed or imaged) in a manner such as that described in Applicant's International Patent Application No. PCT / AU92 / 00199. It is possible to display and to see a stereoscopic image. Thus, an image projected on, formed on, or otherwise displayed on a screen requires displaying the image on the screen, the image being substantially continuous on the screen. Alternately or alternately, includes two or more adjacent angular fields of view spaced about a common center that are displayed in a split and separated manner. These separate divisions are visible through portions of a grid, as described with respect to Figures 1 and 2 of the accompanying drawings, which grids have dimensions substantially corresponding to the dimensions of the divisions of the image displayed on the screen. And a portion having a shape or an opening. The grid means is arranged at a distance from the screen and the resulting image segmentation to the left of the center of the common image is substantially visible only to the left eye of the observer through the grid portion, while the center of the common image is The divided portion of the image obtained on the right side of is substantially only visible to the observer's right eye through the grid portion. The relationship between the left part and the right part of the image relative to the grid and its part is kept substantially as the part of the grid vibrates, allowing the image to be seen through its vibrating grid and its vibration. Ensures that the image is visible to the observer's eyes (through the grid means) at a rate such that it appears as a coherent, fully stereoscopic image and is synchronized with the display of the image subdivisions. This has been found to avoid flickering all or part of the appearance of any individual angle of view, and the grid portion, when vibrating, causes a substantial difference between the eyes of the observer and the screen. It became clear that it became virtually invisible as a transparent window part. It should be understood that applications and modifications of the invention are possible without departing from the scope and spirit of the invention as claimed.

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Claims (1)

[Claims] 1. View two or more angles spaced around a common center to create a stereoscopic image. Including a field, including the step of displaying a divided and separated image on the screen, The separated divisions of the image substantially correspond to the dimensions of the separated divisions of the image. Visible through grid means of different sizes and shapes, Are placed at a distance from the screen and are to the left of the center of the common image The divided portion of the obtained image is substantially visible to the observer's left eye through the grid. On the other hand, the divided parts of the image obtained on the right side of the center of the common image are realized through the grid. Qualitatively with respect to the right eye of the observer, with respect to the segment of the image that appears on the screen The grid is substantially synchronized and coherent to the observer's eyes By vibrating at a speed that forms a complete stereoscopic image, To the left side and right side of the image. And a method characterized by: 2. Two or more angles, spaced about a common center, in a way that creates a stereoscopic image Displaying an image containing a field of view on a screen surface, the angular field of view being divided. And a separated and separated angular field of view of the image Visible through a grid of dimensions and shapes that substantially correspond to the dimensions of And the grid is at a distance from the screen to the left of the common image centerline. The divided portion of the image obtained on the side is substantially left of the observer through the above-mentioned grid portion. While visible, the segment of the image obtained to the right of the center of the common image is the grid part. The screen is positioned so that it is substantially visible to the right eye of the observer throughout the minute. When the above image is displayed on the front, at the speed of forming a coherent and complete stereoscopic image. By vibrating the part of the grid synchronized with the display of the divided parts of the image , So that the relationship of the left and right divided parts of the image to the grid part is maintained The method characterized in that 3. A method of forming a stereoscopic image that allows for two or more spaced-apart angular views around a common center. Displaying an image containing a field on a screen surface, the angular field of view being divided. And separated and the divided and separated angular field of view defines the size of the divided portion of the image. As seen through the portion of the grid whose size and shape corresponds substantially to the law. And the grid is located some distance from the screen, to the left of the center of the common image. The divided portion of the image obtained is substantially visible to the left eye of the observer through the portion of the grid. On the other hand, the divided part of the image obtained to the right of the center of the common image passes through the grid part. The image is then placed so that it is substantially visible to the observer's right eye. When displayed on the screen, the part of the grid shows a coherent and complete stereoscopic image. By vibrating in synchronization with the display of the divided parts of the image at the forming speed, The relationship between the left and right divided parts of the image with respect to the grid part is maintained, The part of the lid is a transparent window between the eyes of the observer and the screen. A method characterized by being rendered substantially invisible. 4. A method for forming a stereoscopic image according to any one of claims 1 to 3 And the grid means is in the form of a screen comprising electro-optical material. A method for forming a three-dimensional image characterized by: 5. A method for forming a stereoscopic image according to any one of claims 1 to 4 And the grid means is in the form of a liquid crystal screen. A method of forming a body image. 6. A device for forming stereoscopic images that allows two or more adjacent units to be separated about a common center. Means for displaying on a screen surface an image containing a divided and separated angular field of view And the divided and separated angular field of view of the image is proportional to the dimensions of the divided portion of the image. As seen through the parts of the grid that have qualitatively corresponding dimensions and shapes A grid means provided in front of the screen, The steps are separated from the screen by a distance and are located to the left of the center of the common image. The divided part of the displayed image is substantially visible through the part of the grid to the left eye of the observer. On the other hand, the image division obtained to the right of the center of the common image is substantially the grid part. Visible to the observer's right eye throughout the minute, displaying the image on the screen Maintain the relationship of the left and right split parts to the grid part On the screen at a speed that produces a coherent and perfect stereoscopic image. The grid means and the grid are substantially synchronized with the display of the divided parts of the image. Means are provided for vibrating the grid means so that the parts vibrate. A device characterized by. 7. A device according to claim 6, wherein the grid means is electro-optical. A device characterized in that it is in the form of a screen comprising material.   8. The device according to claim 6 or 7, wherein the grid is a liquid crystal screen. A device characterized by having a clean form.