JP2006319932A - Multi-dimensional input, output, transfer, arbitrary memory, and production proportional method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To acquire and display a real-time (run-time) three-dimensional object or image. <P>SOLUTION: A color 3D image input device (digitizer) and a 3D image output device (display) capture and show 3D images having the light fields. Positions, angles, directions, phases and colors of the light fields are controlled by various methods such as liquid crystal masks with photo-sensors, liquid crystal masks with patterns. Alternatively, micro-lens-array, micro-pinholes, liquid crystal pinholes, varifocal micro-lens arrays and varifocal index-gradient lens, etc., are used together with high-resolution and high-speed pattern generating means with photo-sensors and photo-emitters. This can be used for 3D communication, 3DTV, 3D camera cloaking devices. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  3D input and 3D display device

In the traditional way, it is a real-time (runtime) object of three dimensions, or a special glassless multiplex in space only with a light or special three-dimensional scanner that is difficult to acquire and display an image. Seen by the user.
There are about three dimensions of digitizer and display available.
A fast and good digitizer is L.A. D. I. Was created to acquire 3D images. They use a triangular laser wave to obtain a line on the object and analyze the three-dimensional shape. However, this does not fit very well in acquiring 3D motion but takes some time.
The virtual headphones show two user images that differ from each eye by the screen to create an image of three dimensions. The shutter glasses can also show three-dimensional images with alternating, left and right images that are changing quickly. But many people wear such devices that feel uncomfortable, and some become cyber, ill, easily.
Those holograms show images of three dimensions. However, these images are difficult because they can be changed in real time (runtime).
Spiral screen that rewards the screen to create a plate, three dimension image show (only the shape of the surface of the image and does not indicate that they are real three dimension images) The conventional method of projecting an image of two dimensions to rotate the. (Reality, Felix, Legislative Research), conventional method of predicting that two dimensional images on multiple of a semi-transparent plate to create a three dimensional image are very expensive because they are multiple , DMD, GLV cost, much. US Patent 5,394,202 (Dealing, 1995) and US Patent No. 5,907,312 (Sato et al., 1999) release some of these methods.
In Japanese Patent, No. 288957, or H01-193836 (Felix Gascia, et al, 1989) shows how to turn a three-dimensional image from a project into a two-dimensional image by rotating the plate. This is a collection of red, blue and green laser beams collected into a light fiber and a light to create an image of two dimensions, bent and rotated into a plate, so that it appears three Dimension image, the result. However, it is spinning fast enough to hurt the user. Therefore, touching the three-dimensional image created by this device is not appropriate for the user. Similarly, this is almost impossible by itself to show an image in space only by light.
In US Patent No. 3,647,284 (Virgil B Ethlgs et al., 1972), show how to show an image of three dimensions created by light originally scattered by an object. The two dishes placed on this device mean to face each other. The top dish method has an annular state (which is to have a hole in the middle), and when the user places an object on the bottom of the bottom dish method, an image of the three dimensions is on this hole. appear. Each dish has a reflecting material interior for reflecting light. However, this device would be inappropriate alone to show that real time (runtime) is an image of three dimensions. Because it consists of two plates.
Sharp and 3DT have developed a two-eye method three-dimensional display for flat panels. Users can see from one angle and cannot place themselves anywhere to see a 3D image.
SANYO has developed a three-dimensional display that uses pinholes. Other than those methods, making a flat panel is not easy, it requires an extra-bright light source behind. Similarly, it is difficult to use current technology for manufacturing. It tends to be expensive. Similarly, data conversion from 3D objects to 2D liquid crystal takes too long time for runtime applications. And their determination is low.

1. Realistic 3D images can be displayed.
2. Multi users can see 3D images 3. Will show both 2D and 3D images.
4). 4. Can be easily manufactured using current 2D display technology. Capture and display conversion time is small.
6). The amount of data is small.
7). Conversion time for data compression and data decompression is small.
8). Bending system. Bending system.

The present invention makes it easy to input, interpret, judge and output information, waves, light and sound. It is also possible to perform linear conversion using a decoder such as a DSP. A three-dimensional image is obtained by a digitizer and displayed on a display. Three-dimensional information is obtained in the ER element through a pinhole, a microarray lens, or a wave handler, and is appropriately converted and displayed on a three-dimensional display. This may be a dynamic multilayer type. A liquid crystal using high-speed switching using CGS (continuous particle silicon) or the like for the TFT of the ER element, or an input / output using an organic material may be used. At this time, the three-dimensional data may or may not be converted into a three-dimensional coordinate system.
The device of the invention detects a dynamic image that captures a device like an optical sensor, the placement of the optical sensor, the matrix of the optical sensor, the muscles of the optical sensor, the muscle tension, and the dynamic image of the moving body Sensor to acquire, C.I. C. D. Acquire images of three dimensions by having multiple layers of CMOS, optical sensors, and / or patterns that produce multiple patterns that move with the mask, mask, method.
There is a pinhole lens that guides light to an ER element (imitter, receiver element, optical element) or fluctuates with patterns. The color intensity (including white, black, and gray), position, and direction of light is identified by structure and sensor. This can be done for single and / or multi-layers of pinhole (pattern) masks. One or more pinholes may be selected according to the application. In particular, in a plurality of cases, this pattern may be used for calculation (or instructing use) of the mask pattern of the 3D display. Acquire 3D image, position and direction of information, wave and color. The present invention thereby reduces much computation time.
The inventive device can display an image of three dimensions by creating a light or light field distribution of virtual data. And or it can use a pattern mask. Examples are shown by Kazutora Yoshino with Application Numbers 10 / 628,541 and 10/63869.
Position multiple cameras, use a camera with multiple inputs, move the motion camera vertically and horizontally, change the angle vertically and horizontally, move and move multiple From this, you can analyze, understand and know 3D data.
In this case, geometrical calculations and analysis based on image / information changes and speed (may include multiplication / division methods) that come from the movements made it possible to more effectively calculate the three-dimensional depth. .

This invention has advantages related to the prior art. This can acquire and display 3D images with realistic dimensions such as time and space.
1. of the invention This device can display a true realistic 3D image as if it were there.
2. Multiple 3D images can be viewed by multiple users. Both 2D and 3D images will be shown.
4). 4. Can be easily manufactured using current 2D display technology. Capture and display conversion time is small.
6). The amount of data is small.
7). Conversion time for data compression and data decompression is small.
8). Bending system. Bending system.

BEST MODE FOR CARRYING OUT THE INVENTION

The best mode of the invention is communication of information by ER (element) of information.

  When handling the ER element, liquid crystal using high-speed switching using CGS (continuous particle silicon) or the like for the TFT, or input / output using organic materials may be used. At this time, the 3D data may or may not be converted to a 3D coordinate system.

An information handler is also the present invention by combining pinholes, slots, lenses, speakers, microphones, micro units and materials that can input and output information. Computer analysis is also part of the core.

It may be used for applications that are more varied by selecting light, wave position, direction, color, phase, shape, type, etc.

      The preferred embodiment of the 3D Image Scanner and Display invention is illustrated in FIG. FIG. 1 shows an example diagram of a 3D image scanner and display system. This can be made with a fast response liquid crystal panel by polarizing the plate to acquire angle, position and color. Fast liquid crystal creates a pattern of slot arrays. Rays entering the slot are C.I. C. D, will be obtained in optical sensors such as CMOS. This reads the ray position and the color direction. By changing the slot position quickly, it reads the entire ray distribution. Optionally, analyzing this light distribution and transferring the pattern to a 3D display, it can show a 3D image. This may be done in one form, such as a 3D camera, or in a complex or distant form such as an internet connection for 3D communication. For example, it may acquire a 3D image of a user at one location on the Earth that may show a 3D image of the other user. Similarly, this will be done with full fields. The light enters the slot where the light passes to the sensor.       FIG. 2 shows another embodiment. Those lights enter a slot through which the light passes to the sensor.       FIG. 3 shows an example diagram of an alternative 3D image scanner and display from side view. The mask has a relatively long slot. This increases the technical speed. Randomly, a long slot will move such as rotationally or diagonally or horizontally (vertically) as well. This can be made with a fast response liquid crystal panel by polarizing the plate to acquire angle, position and color. Fast liquid crystal creates a pattern of slot arrays. Rays entering the slot are C.I. C. Would be obtained in an optical sensor such as D. This reads the ray position and the color direction. By changing the slot position quickly, it reads the entire ray distribution. Optionally, analyzing this light distribution and transferring the pattern to a 3D display, it can show a 3D image. This may be done in one form, such as a 3D camera, or in a complex or distant form such as an internet connection for 3D communication. For example, it may acquire a 3D image of a user at one location on the Earth that may show a 3D image of the other user.       FIG. 4 shows another embodiment. An example diagram of a 3D input device and an output device is shown. This is an example of a pinhole / slot, but a combination of a pinhole and a microlens array may be used. An example diagram of a 3D input device and an output device is shown.       FIG. 5 shows an example diagram of another form of application of the 3D input device and 3D output device. It will have 3D camera form, 3D video, 3D communicator.       FIG. 6 shows another embodiment. An example diagram of a 3D input device and an output device is shown. This is an example of a microlens array / lenticular, but a combination of a pinhole and a microlens array may be used. An example diagram of a 3D input device and an output device is shown.       FIG. 7 shows a diagram of an example application.       FIG. 8 shows a diagram of an example application. Information and images may be recorded through a memory.       FIG. 9 shows an example diagram of an application. If we make this with flexible materials such as fiber, plastic, etc., it will be used as a cloaking device. One side can receive a three-dimensional image and show the three-dimensional image on the opposite side as if there were no objects present in the cloaking device. If the SDF uses this, it will have a very durable material such as bullet tested material / fiber. And in order to avoid infrared detectors / sensors, it may also have a thermal control sheet. There will be more materials added appropriately. The unit that receives and emits photons having an ER element may be the same unit. Several sheets of highly functional material / structure film may be stacked. It may be divided into units like clothes. These ER elements can also be made by vapor deposition, jet, imitter & receiver manufacturing.       FIG. 10 shows an example of the energy state of the ER element.       FIG. 11 shows an example of three-dimensional coding.       FIG. 12 shows image input and output devices.

Explanation of symbols

Reference numerals in the figure (1) Light field A bright vector field of three dimensions, a conservative bright vector field such as a parallel beam field, and a non-conservative bright vector field are virtual light points, virtual (light / light ) Point, distributed virtual field scanned (10) mask, micro-pinhole lens array, micro-lens array, index-gradient, such as pinhole lens array, which means the lens method of the focus of the microlens With lens array, liquid crystal pinhole lens array, electro-eye micro-lens array, nematic / ferroelectric liquid crystal array, polarizing plate, two dimension image pattern maker (variable focus micro-lens arrays) Crystal panel. TFT using CGS.
Fast phase-variable panel, liquid crystal panel, plate, ferroelectric liquid crystal panel, plate, micro-lens array, pinhole lens array moving micro-lens array moving screen moving pinhole lens array moving pinhole lens array A liquid crystal panel that can polarize a ferroelectric liquid crystal panel with
Variable focus lens, electro-optic micro-lens array, variable focus pinhole lens, variable focus index-gradient lens, variable focus liquid crystal lens, piezoelectric lens, (super) acoustic-micro-lens array, variable focus Liquid crystal, full-nel lens,
Pinhole lens, pinhole lens array, micro-lens, micro-lens array, liquid crystal pinhole lens (array), electro-eye micro-lens (array), liquid crystal, nematic / ferroelectric liquid crystal, plate, two dimensions Image pattern maker, variable focus micro-lens (array), liquid crystal panel that can polarize index-gradient lens (array),
Mask, two-dimensional image pattern maker, liquid crystal, nematic / ferroelectric liquid crystal, liquid crystal that can polarize the plate. (15) Optical sensor method and / or photo-optical sensor, CCD, array or photographic sensor, optical sensor matrix, photosensor strut, sensor, optical sensor multi-layer.
(20) Image display method of dimension 2 Liquid crystal display device, ferroelectric liquid crystal, nematic liquid crystal, plate, micro-liquid crystal array, plate, plate, plasma display, organic electroluminescent display, laser array, micro-laser array Such as a diode laser array, a nano-2D pattern generator (light diffraction generator), a liquid crystal panel that can polarize a micro-liquid crystal array by polarizing a ferroelectric micro-liquid crystal array by polarizing a CRT thing.
(30) Light source method Light source, constant diode light emitter, arc lamp with optics, light fiber with light source, laser, laser with optics, parallel beam generator, light conservative vector field generator, plate, polarized It is like a light source by polarizing a light source.

Claims (5)

A system comprising a group comprising a method and means for acquiring, analyzing, improving, judging and expressing multidimensional information having means, method fields and information fields in space in real time. The system according to claim 1, wherein the means for acquiring the field includes a multi-dimensional input system, an input device, a light receiving element, a light sensor, a liquid crystal pattern generator, a panel, a CGS TFT, a joint unit, an acoustic element, a microphone, an input device, Multi-dimensional input device, 3D input device, 3D digitizer, 3D scanner, micro-array lens, liquid crystal pattern generator, polar panel, control, optical sensor, solid sensor, particle sensor, superstring sensor , Multi-dimensional camera, motion camera,
A system that includes an appropriate group of combinations in a component. 2. The system according to claim 1, wherein the means for expressing the field is a multidimensional information output system, an output device, a multidimensional information system for outputting the multidimensional information / method, and transferring the information / method, a multidimensional field / information. System controlling method, optional multi-dimensional information analyzer, optionally multi-dimensional information recorder, output device, multi-dimensional output device, three-dimensional display, multi-dimensional full speaker, rigid panel, rigid unit, A system that includes a group of appropriate combinations of particle emitters and superstring emitters. 2. The system according to claim 1, wherein the means for analyzing, improving, and judging is wire, wireless internet, computer, integrated circuit, information transfer, wave signal transfer, wave signal modulator, battery, antenna, radio, wave signal controller, neural network. A system that includes a group of appropriate combinations in the network, fuzzy system, controller, and Yoshino system. The system of claim 1, wherein
Field acquisition units,
Field output unit,
Bulletproof vests about bullets,
Temperature control waistcoat,
A cloaking system or device that hides an object as if it were missing, characterized in that it has a system that includes the appropriate group of combinations in the component.

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