WO2008073000A1

WO2008073000A1 - Stereo image producing system

Info

Publication number: WO2008073000A1
Application number: PCT/RU2007/000649
Authority: WO
Inventors: Evgeny Borisovich Gaskevich
Original assignee: Evgeny Borisovich Gaskevich
Priority date: 2006-12-12
Filing date: 2007-11-21
Publication date: 2008-06-19
Also published as: RU2326507C1

Abstract

The invention relates to colour stereo image producing systems and can be used for developing stereoscopic computer monitors and TV-sets. Said invention makes it possible to produce a high-definition colour stereo image which is devoid of geometrical distortions and has a wide field of view. The components (colour channels) of the inventive system can be displayed simultaneously or not, for example sequentially. In the first case, when the left image of a stereopair is displayed, the illumination source or the set of illumination sources corresponding to the set of primary colours Zleft operates, and when the right image of a stereopair is displayed, the illumination source or the set of illumination sources corresponding to the set of primary colours Zright operates. In the second case, when each component (a colour channel) of the image is displayed, the illumination source of a corresponding primary colour operates. In the case of the sequential display of components (colour channels) of the image, when only one component is displayed at each instant, the matrix display devoid of the matrix of spectral filters can be used.

Description

Stereo imaging system

The technical field to which the invention relates.

The invention relates to systems for forming color stereo images and can be used to create stereoscopic computer monitors and televisions, stereo cinema and other analog and digital means of displaying information.

Mostly the invention is intended to create color stereoscopic liquid crystal monitors and televisions.

In addition, the invention can be used to demonstrate stereoscopic information at exhibitions, in museums, theaters, concert and sports halls, stadiums and sports fields, in video ads, in medicine, in computer-aided design systems, in cars, game and training systems, and in other areas of technology where the use of color stereoscopic images is required.

BACKGROUND OF THE INVENTION Matrix systems (screens, displays) for reproducing a two-dimensional color image are known in the art, where an image is formed on a matrix of color reproducing elements, which is a screen (that is, an image is formed directly on the screen that the viewer sees). These are televisions, computer monitors, and other systems designed primarily for personal use. The main types of arrays (screens, displays) used in such systems are liquid crystal displays (LCD screens) with backlight sources, plasma panels (PDP screens), picture tubes (CRT screens), LED displays (LED screens), etc. Projection systems for reproducing a two-dimensional color image are known in the art, where an image is formed on a relatively small matrix (or a set of matrices) color reproducing elements, and is projected onto a large screen that the viewer sees using a powerful light flux and an optical system (including a lens or a set of lenses and other elements). These are projection televisions, as well as systems of video projectors with an external screen, intended mainly for collective use. The main types of matrices used in such systems are liquid crystal luminance displays (LCD matrices), liquid crystal reflective displays (LCOS and D-ILA matrices), micromirror electromechanical panels (DLP chips) and other types of color matrices, and black and white and monochrome picture tubes (cathode ray tubes, CRT).

In the prior art there are several methods of forming a stereoscopic image (spectacle - polarizing and obturator, frameless raster, etc.). However, all existing methods have disadvantages that do not allow them to be used to create matrix systems for reproducing color stereo images suitable for practical use and wide replication. The best illustration of this statement is that in the consumer market there are still no color stereoscopic liquid crystal, plasma or kinescope monitors and televisions, while the demand for them would be enormous. Some existing methods for forming a stereoscopic image are currently used in projection systems for reproducing color stereo images. Consider the existing methods of forming a color stereoscopic image and their disadvantages.

A stereoscopic imaging system is known from the prior art, in which for separate eyewear observation of the left and right frames, stereopairs respectively provide the viewers with polarized or obturator glasses with the left and right eyes (see book: Valius H. A. Stereo: Photography, film, television. -M .: Art, 1986, - 263 s, ill.). Polarization is used in two versions - linear (for example, for the left eye - vertical, for the right - horizontal) and circular (for example, for the right eye - the right, that is, clockwise, and for the left eye - the left, that is, counterclockwise , or vice versa). Positive effects when using polarizing or obturator stereo glasses are the possibility of simultaneous observation of full-color stereo images by a large number of viewers in a wide viewing angle, as well as ensuring equal light load on the eyes of viewers. The main disadvantage of linearly polarized systems is that tilting the viewer's head left or right significantly reduces the quality of the stereo effect (leads to a bifurcation of the image), and at large tilt angles the stereo effect completely disappears. The viewer must strictly keep his head so that his eyes are at the same level horizontally.

The main disadvantage of systems with circular polarization is that to ensure circular polarization, not a film is needed (as for linear polarization), but a rather complex polarization filter. At the same time, circular polarization has a significant advantage over linear polarization - tilting the head does not affect the quality of the stereo effect.

A common drawback of all polarization methods is that it is almost impossible to use them to create matrix systems for generating color stereoscopic images. For this, microscopic polarizing filters would have to be applied, alternating with the polarization directions, on each pixel of the matrix monitor, which is technologically extremely difficult. The use of polarization methods to create stereoscopic liquid crystal monitors and televisions is also complicated by the fact that already polarized light is used in the liquid crystal display. Currently, polarization methods are used only to create projection systems for the formation of color stereo images. The main disadvantage of the obturator method is eye fatigue due to low-frequency flickering of not only the image on the screen, but also of the environment, which causes irritation and even eye disease during prolonged observation of stereo images. The drawback of the obturator method is the need to use heavy glasses, powered by a battery or from an external source.

Glasses-free stereoscopic projection systems with lens-raster stereo screens are also known in the art. The main disadvantage of lens-raster stereoscopic systems is the need for motionless retention of the viewer's head in areas of selective stereoscopic vision. The width of each zone of vision does not exceed the distance between the pupils of the eyes, while the shift of the eyes relative to the center of the zone by two or more centimeters leads to a significant decrease in the brightness of the observed image. If the viewer changes position and leaves the zone of vision, the stereo effect is lost. Strict fixation of the position of the viewer relative to the zones of vision even for several minutes causes the viewer's discomfort - inconvenience, fatigue, as the viewer is forced to sit still and constantly visually look for the optimal angle (center of the zone of vision) of a clear observation of the stereo effect.

In addition, a prior art method for generating stereo images based on the use of different colors for the left and right frames of a stereo pair is known. For example, they take the left frame - red, and the right frame - green, and project on one screen, and use glasses with filters - red and green. Thus, the viewer sees with one eye only the red (left) frame, and with the other - only the green (right) frame, and as a result sees a three-dimensional image. The main disadvantage of this method is that with its help it is impossible to ensure the formation of color stereo images with natural color reproduction.

A known method and system for the formation of color stereo image through the use of various sets of basic colors for different eyes, which is the closest analogue of the present invention (WO 2000/074392 Al (Daimler Chrusler AG), priority May 26, 1999). Also known are stereo projection forming systems built on this principle (WO 2005/039192 Al (BARCO NV), priority October 21, 2003). However, in both of these patents we are talking only about projection systems, which is explicitly indicated in the claims. The present invention contemplates matrix displays for generating stereo color images through the use of different sets of base colors for different eyes, using backlight sources corresponding to different sets of base colors. According to the international search report conducted on a similar application PCT / RU2006 / 000324, such systems are not known from the prior art, which makes their patenting possible. The technical result to which the present invention is directed is to create a system for generating color stereo images, providing the formation of color stereo images with high definition, without geometric distortion, with natural color reproduction, with maximum resolution and wide field of view.

SUMMARY OF THE INVENTION

The claimed technical result is achieved by the fact that the stereo imaging system comprises: a matrix display with a backlight, designed to generate and alternately display the “left” and “right” frames of the stereo pair using sets of base colors Z _left and Z _right, respectively, and a filter device designed for separate observation of the “left” and “right” frames of a stereo pair with different eyes of the viewer by filtering the colors of the sets of Z _left and Z _right in

The matrix display has at least one backlight source or a set of backlight sources that provide illumination of the matrix display alternately with the spectrum corresponding to the set of basic colors Z _left and with the spectrum corresponding to the set of basic colors Z _right in synchronization with the display of the corresponding frames on the matrix display. The “left” frame of a stereo pair is decomposed into components (color channels) according to the set of base colors Z _lev , which includes at least three spectrally independent colors. The “right” frame of a stereo pair is decomposed into components (color channels) according to a set of basic colors Z _rights , which includes at least three spectrally independent colors, each of which does not match any color from the set of basic colors Z _left .

In one embodiment of the invention, all components (color channels) of the frame are displayed on the matrix display at the same time. When displaying the "levogo" stereopair frame works backlight source or set of illumination sources corresponding to the set of primary colors Z _lev, while displaying a "ppavogo" stereopair frame works backlight source or set of illumination sources corresponding to the set of primary colors Z _ppav. The backlight sources can be turned on during the display of a frame in any mode, combination and sequence - simultaneously, sequentially, etc. It is only important that during the display of the frame they provide the required average backlight intensity with a spectrum corresponding to the set of basic colors for this frame.

In another embodiment of the invention, the components (color channels) of the frame are not displayed simultaneously, for example, sequentially in time. When displaying each component (color channel) of the frame, the backlight source of the corresponding base color is turned on. In this case, a matrix display containing a matrix of spectral filters can be used, or a matrix display without a matrix of filters.

In one embodiment, lasers or narrow-band LEDs are used as backlight sources, appropriate set of basic colors Z and Z _ppav _lev. In yet another embodiment of the invention as illumination sources are lasers and combinations of spectral filters or a combination of LEDs and narrow-band spectral filters corresponding sets of primary colors _lev Z and Z _ppav.

In yet another embodiment of the invention, the backlight source is positioned so that the light flux emitted by the specified backlight source passes through the matrix display.

In one embodiment, a liquid crystal screen (LCD screen) is used as a matrix display.

In yet another embodiment, the matrix display comprises an array of spectral filters. In yet another embodiment, the emission spectra of one backlight source from a set of Z _left and one backlight from a set of Z _right fall into the transmission region of each spectral filter of a matrix display.

In another embodiment of the invention, the filter device consists of at least two spectral filters, one of which transmits the colors of the set Z _left and does not pass the colors of the set

Z _P right, and another spectral filter passes the colors of the set Z _right and does not pass the colors of the set Z _left. At the same time, a spectral filter that transmits the colors of the set Z _left and does not pass the colors of the set Z _left is located between the display device and the left eye of the viewer, and the spectral filter, that transmits the colors of the set Z _right and does not transmit the colors of the set Z _left is located between the display device and the right eye of the viewer.

In another embodiment of the invention, the filter device is made in the form of at least one holographic optical element, which is located between the matrix display and the eyes of the user. In yet another embodiment of the invention, the stereo imaging system may be configured to further generate a two-dimensional image.

Brief Description of the Drawings

In FIG. 1 shows a representation of sets of base colors and their corresponding color spaces in the x and y coordinates of the CGR model.

In FIG. Figure 2 shows the formation of a color stereo image with the decomposition of the “left” and “right” frames of a stereo pair into different sets of basic colors in matrix systems, using two sets of three basic colors as an example.

In FIG. Figure 3 shows the formation of stereo images with alternating display of “right” and “left” frames, with the simultaneous display on the matrix display of all components (color channels) of the frame.

In FIG. Figure 4 shows the formation of a stereo image with alternating display of "right" and "left" frames, with sequential display on the matrix display of the individual components (color channels) of the frame, using a matrix display without a matrix of filters.

DETAILED DESCRIPTION OF THE INVENTION

The ability of a person to see a stereoscopic (volumetric) image in the near zone (conditionally up to 5 m) is primarily due to the binocular mechanism of human vision. When we look at an object located close enough to us, two different two-dimensional images are formed on the retina of the left and right eyes, which are perceived by the brain as one three-dimensional (three-dimensional) image. Accordingly, if we create two two-dimensional images (frames) that correspond to the gaze with the left and right eyes (the so-called stereo pair), and make the left eye only see the “left” frame stereo pairs, and the right eye is just the “right” frame of the stereo pair, you can create a stereoscopic (surround) image.

A plurality of colors perceived by a person can be represented in x coordinates and in the CIP model, FIG. 1 (light gray area). Any set of three (or more) spectrally independent colors (base colors) defines a color space (a triangle in the X and Y coordinates of the CIP model), all of whose colors can be obtained by mixing these base colors in various proportions. For example, in FIG. Figure 1 shows two color spaces defined by two different sets of three basic colors (red, green and blue) - a set Z _\ = {Ri, Gi, Bi} and a set Z ₂ = (R ₂ , G ₂ , B ₂ ). Any color C falling into the intersection region of these color spaces (the dark gray region in Fig. 1) can be decomposed into a set of Zi and a set of Z ₂ .

For forming a color stereoscopic image, using a display device form a "levy" and "ppavy" frames of the stereopair are laid "levy" and "ppavy" frames of the stereopair in components (color channels) for two different sets of primary colors Z _lev and Z _prosp AIn respectively, and then both frames are displayed using a display tool on the screen that the viewer sees, the “left” frame is displayed using a set of base colors Z _left and the “right” frame is displayed using a set of basic colors Z _right - A set of basic colors Z _left in includes at least three spectrally independent colors, and the set of base colors _Zpra includes at least three spectrally independent colors, each of which does not match any color from the set of basic colors Z _lev . The “left” and “right” frames can be displayed simultaneously or alternately.

The display device comprises a dot matrix display for forming and alternately display "levogo" and "ppavogo" stereopair frames, and the illumination source (or a set of illumination sources) intended to illuminate the matrix display alternates with a spectrum corresponding to the set Z _lev basic colors, and with spectrum corresponding to the set of basic colors Z _Right , synchronously with displaying the corresponding frames. The “left” frame of a stereo pair is decomposed into components (color channels) by a set of basic colors Z _left , and the “right” frame of a stereo pair is decomposed into components (color channels) by a set of basic colors Z _right - Components (color channels) can be displayed simultaneously or not simultaneously , for example, sequentially.

Then the colors of the sets of Z _left and Z _{right are} filtered using a filter device so that the viewer sees with the left eye the “left” frame of the stereo pair and does not see the “right”, and with the right eye sees the “right” frame of the stereo pair and does not see the “left”.

In one embodiment of the invention, the filtering device is a set of at least two spectral filters - a “left” spectral filter that transmits the colors of the set Z _left and does not transmit the colors of the set Z _right, and a “right” spectral filter that transmits the colors of the set Z _right and the color- _tight set of Z _left . In this case, the spectral filters are arranged in such a way that a spectral filter that transmits the colors of the set Z _left and does not transmit the colors of the set Z _right is located between the viewer's left eye and the display device, and a spectral filter that transmits the colors of the set Z _right and does not pass the colors of the set Z _leB; located between the right eye of the viewer and the display device. Thus, the left eye sees only the “left” frame of the stereopair formed by the base colors of the set of Z _left , and the right eye sees only the “right” frame of the stereopair formed by the basic colors of the set of Z _left , which allows the viewer to see a color stereoscopic (volume) image.

FIG. 2 illustrates the method described above for the case when two sets of three basic colors are used: Z _left = (Ri, Gi, BJ and Z _right = {R ₂ , G ₂ , B ₂ }. In another embodiment of the invention, the filtering device can be performed as custom spectral personal use filters - special glasses, contact lenses, etc.

Custom spectral filters can be of three types - “on exposure”, “on absorption and / or reflection)) and intermediate options.

Spectral filters “on transmittance)) pass narrow spectral bands corresponding to one of the sets of basic colors (Z _left or Z _right ) and do not pass other parts of the spectrum. Thus, spectral filters “on transmission”) darken the environment and allow the viewer to see only the image on the screen (respectively, the left eye of the viewer sees the “left” frame of the stereo pair and does not see the “right”, the right eye of the viewer sees the “right” frame of the stereo pair and does not see “left”).

Spectral filters “for absorption and / or reflection)) absorb or reflect narrow spectral bands corresponding to one of the sets of basic colors (the left does not pass the colors of the set Z _right , the right does not pass the colors of the set Z _left ), and pass the remaining parts of the spectrum.

Thus, spectral filters “for absorption and / or reflection)) do not obscure the environment, and allow you to see how the image on the screen (respectively, the left eye of the viewer sees the“ left ”frame of the stereo pair and does not see the“ right ”, the right eye of the viewer sees“ the right "frame of the stereo pair and does not see the" left "), and the surrounding environment.

Intermediate spectral filter options can have arbitrary transmission spectra, provided that the “left” spectral filter transmits the colors of the set Z _left and does not transmit the colors of the set Z _right , and the “right” spectral filter transmits the colors of the set Z _right and does not pass the color of the set Z _lev .

Custom spectral filters can be combined with ordinary glasses for vision correction. To do this, just apply a filter layer on the lenses of the glasses. Similarly, custom spectral filters can be made using contact lenses. In another embodiment of the invention, the filter device is made in the form of at least one holographic optical element.

In one embodiment, an LCD display (liquid crystal display) is used as a matrix display for image formation. It may contain a matrix of liquid crystal cells and a matrix of spectral filters, or only a matrix of liquid crystal cells without a matrix of spectral filters. A system for generating a color stereoscopic image based on a liquid crystal display will be described in detail below.

As you know, in a standard LCD screen (TV, monitor) a color image is formed as follows. A matrix of microscopic spectral filters of basic colors (usually red, green and blue) is superimposed on a matrix of liquid crystal cells, each of which can change its transparency under the influence of voltage applied to it. Cells and spectral filters superimposed on them can be in the form of strips, circles, etc. with a characteristic size of a fraction of a millimeter. Each color-reproducing pair of “cells + spectral light filter” is usually called a subpixel. The subpixels of each color are evenly distributed across the screen. Usually subpixels are conditionally grouped into groups (one subpixel of each color), which are called pixels.

Behind the screen, a backlight source (broadband lamp) or a set of narrow-band backlight sources (lasers, LEDs) corresponding to a set of basic colors are installed. By changing the degree and time of transparency of the LCD cells, you can adjust the brightness of the respective subpixels. Light from subpixels of different colors is mixed in the perception of the viewer, which allows you to form any color image on the screen. Usually conventionally consider that each pixel reproduces a certain color (by mixing the base colors from its subpixels), and pixels of different colors form a color image on the screen.

In order for the LCD screen to be used for forming a color stereo image, its design must be changed as follows. It is necessary to use two sets of narrowband backlight sources (lasers, LEDs, etc.) corresponding to two sets of basic colors Z _left and Z _right . The “right” and “left” frames are displayed on the screen alternately, while the backlight emission spectrum corresponds to the set of basic colors Z _right when the LCD screen displays the “right” frame, and the backlight emission spectrum corresponds to the set when the LCD matrix displays the “left” frame basic colors Z _lev - spectra of illumination light sources should fall in the spectral region of transmission color filters LSD screen, but to have a sufficient range of diversity for qualitative filter "ppavyx" and "levyx" user frame Spectral filters (spectacles, contact lenses, holographic or diffractive filters and m. p.).

In one embodiment of the invention, all components (color channels) of the frame are displayed on the matrix display at the same time. The backlight sources can be turned on during the display of a frame in any mode, combination and sequence - simultaneously, sequentially, etc. It is only important that during the display of the frame they provide the required average backlight intensity with a spectrum corresponding to the set of basic colors for this frame.

For example, an ordinary LCD matrix with red, green and blue filters can be used, and three pairs of lasers (“left” and “right” red, “left” and “right” green, left and right blue) can be used as backlight ) When the “left” frame is displayed on the LCD matrix, the “left” lasers work; when the “right” frame is displayed, the “right” lasers work. The alternation of frames should occur with such a frequency that the viewer perceives the image continuous in time. Spectra the radiation of each pair of lasers should fall into the transmission region of the corresponding spectral filters of the LCD matrix (for example, the emission spectra of the “left” and “right” red lasers should fall into the transmission region of the red spectral filters of the LCD matrix, see Fig. 3).

In another embodiment, the individual components (color channels) of each frame are not displayed on the matrix display simultaneously, for example, sequentially. In this case, a matrix display (LCD screen) containing a matrix of light filters or a matrix of liquid crystal cells without a matrix of light filters can be used. When displaying each component of the frame, the backlight source of the corresponding base color is turned on.

For example, first, the “red” channel of the “left” frame is displayed on the matrix of LCD cells and the “red” “left” backlight source is working, then the “blue” channel of the “left” frame is displayed and the “blue” “left” is working the backlight source, then the "green" channel of the "left" frame is displayed and the "green" left "source of illumination is working, then the" red "channel of the" right "frame is displayed and the" red "right" source of illumination is working, then the “blue” channel of the “right” frame is displayed and the “blue” “right” sub source is working etki then displays "GREEN" channel block "ppavogo" while working "GREEN" "ppavy" illumination source, etc. (Fig. 4). The display order of the components (color channels) of frames can be any, it is only important that their alternation occurs at such a frequency that the viewer perceives the image continuous in time.

These examples are intended to illustrate the features of the present invention and are not intended to limit the scope of the present invention. All the above systems for forming a color stereoscopic image can be performed with the additional possibility of forming two-dimensional images, by simple design changes, which will ensure the universality of the use of these systems in various fields of technology. For example, a color stereoscopic matrix display can include both a stereoscopic image mode for working with three-dimensional graphics, viewing stereo films, entertainment, etc., and a two-dimensional image mode (with higher light intensity or better color reproduction) for working with text or highly detailed two-dimensional images.

Also, all the above systems for forming a color stereoscopic image can be performed with the additional possibility of forming two independent two-dimensional images for two users (when each user sees only his own image).

Also, more than two sets of basic colors and backlight sources can be used to form several independent two-dimensional and / or stereoscopic images for several users, and several user-defined spectral filters, for independent observation of different images by different users.

Claims

Claim

1. A stereo imaging system based on the use of various sets of basic colors for the “left” and “right” frames of a stereo pair, comprising: a matrix display for forming and alternately displaying “left” and “right” frames of a stereo pair, which has at least one illumination source or set of illumination sources intended to illuminate the matrix display alternates with a spectrum corresponding to the set of Z primary colors into _Le, and with a spectrum corresponding to a set of base colors _ppav Z, with nhronno displaying respective frames, and a filter device for separation of observation "levogo" and "ppavogo" frames of the stereopair by different eyes of the viewer by filtration colors sets of primary colors _lev Z and Z _ppa into-

2. The system according to claim 1, characterized in that the “left” frame of the stereo pair is decomposed into components (color channels) according to the set of basic colors Z _left , and the “right” frame of the stereo pair is decomposed into components (color channels) according to the set of basic colors Z _right .

3. The system according to claim 1, characterized in that the set of basic colors Z _left includes at least three spectrally independent colors, and the set of basic colors Z _right includes at least three spectrally independent colors, each of which does not match with one color from a set of base colors Z _lev .

4. The system according to claim 2, characterized in that the components (color channels) of the frame are displayed on the matrix display at the same time.

5. The system of claim. 4 characterized in that during display of "levogo" stereopair frame works backlight source or set of illumination sources corresponding to the set of primary colors Z _lev, and while displaying "ppavogo" stereopair frame works backlight source or set of illumination sources corresponding to the set of base colors Z _right -

6. The system according to claim 2, characterized in that the components (color channels) of the frame are not displayed on the matrix display at the same time.

7. The system according to claim 6, characterized in that at each moment of time, only one component (color channel) of the frame is displayed on the matrix display.

8. The system of claims. 6 or 7, characterized in that during the display on the matrix display of the component (color channel) of the frame, the backlight source of the corresponding base color works.

9. The system according to claim 1, characterized in that the matrix display comprises a matrix of spectral filters.

10. The system according to claim 9, characterized in that each spectral filter of the matrix display is configured to transmit emission spectra of at least one backlight from a set of base colors Z _left and at least one backlight from a set of base colors Z _pr av-

11. The system according to claim 1, characterized in that an LCD display is used as a matrix display for image formation, which contains a matrix of liquid crystal cells and a matrix of spectral filters.

12. The system according to claim 7, characterized in that a matrix of liquid crystal cells is used as a matrix display for image formation.

13. The system according to claim 1, characterized in that lasers are used as the backlight sources, corresponding to two sets of basic colors Z _lev and Z _P p _av .

14. The system according to claim 1, characterized in that the LEDs are used as backlight sources, corresponding to two sets of basic colors Z _left and Z _right .

15. The system according to claim 1, characterized in that the combination of lasers with spectral filters corresponding to two sets of basic colors Z _left and Z _{right is} used as the backlight sources.

16. The system according to claim 1, characterized in that the combination of LEDs with spectral filters, corresponding to two sets of basic colors Z _left and Z _right, are used as backlight sources.

17. The system according to claim 1, characterized in that the backlight source or a set of backlight sources is located so that the light flux emitted by the backlight source passes through the matrix display.

18. The system according to claim 1, characterized in that the filtering device consists of at least two spectral filters, one of which passes the colors of the set Z _left and does not pass the colors of the set Z _right , and the other filter passes the colors of the set Z _right and not skips the colors of the set Z _lev .

19. The system according to claim 18, characterized in that a spectral filter that transmits the colors of the set Z _left and does not transmit the colors of the set Z _right is located between the display device and the left eye of the viewer, and a spectral filter that transmits the colors of the set Z _right and does not pass the colors of the set Z _{the left} is located between the display device and the right eye of the viewer.

20. The system according to claim 1, characterized in that the filtering device is made in the form of at least one holographic optical element, which is located between the matrix display and the user's eyes.

21. The system according to claim 1, characterized in that it is made with the additional possibility of forming a two-dimensional image.

22. The system according to claim 1, characterized in that it is made with the additional possibility of forming two independent two-dimensional images.

23. The system according to claim 1, characterized in that it is made using more than two sets of basic colors and with the possibility of forming several independent two-dimensional and / or stereoscopic images.