RU2294002C2 - Projection system - Google Patents

Abstract

FIELD: projection systems.

SUBSTANCE: projection device includes light source, collimating optical system, at least one amplitude modulator, at least one scanning element, correcting optical system, polygonal mirror, rotary optical element, screen mirror and dissipating screen. Polygonal and screen mirrors are made in form of arrays of micro-mirrors, and number of positions of light beam at outlet of scanning element, composing a two-dimensional structure, is equal to number of micro-mirrors of polygonal mirror and number of mini-mirrors or screen mirror.

EFFECT: decreased dimensions, improved image quality.

24 cl, 5 dwg

Description

The present invention relates to optics, in particular to projection devices, and can be used in projection televisions, as well as in other similar devices.

In projection systems with laser beam scanning, horizontal and vertical scanning of the laser beam is performed to form an image. The key role is played by the speed of movement of the beam across the screen, on which the quality of the resulting image depends.

Known projection device (US patent No. 6170953), which includes a set of optical elements for beam forming and a rotating polygonal mirror that performs a horizontal scan of the light beam on the screen.

Another US Pat. No. 6,724,509 describes an optical projection device that consists of a light source, a beam splitter, dichroic mirrors, a high-quality mirror, a lens, focusing lenses, acousto-optical modulators, a beam combiner, dichroic mirrors, a polygonal mirror, projection lenses, a galvanometer, a mirror, and screen. The light source is a white light laser emitting white light. A semiconductor laser red (R), green (G), cyan (B) or a solid-state laser with wavelength conversion can be used as a light source. A beam splitter divides the light into monochrome R, G, and B rays of colors. The beam splitter consists of two dichroic mirrors and a high-quality mirror. Dichroic mirrors separate white light passing through the lens and refracted by a high-quality mirror into R, G, B rays, a high-quality mirror refracts a monochromatic beam passing through a dichroic mirror. The separated monochromatic rays R, G and B are focused by focusing lenses, pass through acousto-optical modulators (AOM) and are modulated in accordance with the image signal. To collimate the modulated laser beams back into the same parallel beams as before entering the focusing lenses, collimating lenses are placed next to the AOM. Using a beam combiner, the rays R, G and B, modulated in accordance with the image signal, are combined into one combined beam. The beam combiner consists of two dichroic mirrors, as well as a high-quality mirror. The combined beam hits the polygon mirror at a certain angle using high-quality mirrors. Since the combined beam hits the polygon mirror used as a horizontal scanning device, the combined beam is scanned horizontally. A horizontal scanning beam passes through projection lenses that are located between the polygonal mirror and the galvanometer, and focuses on the mirror side of the galvanometer. A laser beam spot focused on a galvanometer is scanned vertically. An image scanned by a polygon mirror and a galvanometer is projected onto the screen using a mirror located above the galvanometer and facing the screen. This device is the closest in concept to the claimed solution and is selected as a prototype.

The disadvantage of the above prototype and analog of the claimed invention is the limited horizontal speed carried out by the polygonal mirror, due to the limited rotation speed of the mechanical drive of the polygonal mirror. In addition, the disadvantage of analog and prototype devices is the inability to reduce their thickness due to the significant size of the polygonal mirror.

The problem to which the claimed invention is directed is to create a projection device with reduced dimensions due to the removal of a traditional polygonal mirror, which allows to increase the horizontal scan speed and, thus, improve the image quality.

The technical result is achieved by creating a projection device that includes a light source, a collimating optical system, at least one amplitude modulator, at least one scanning element, a correcting optical system, an advanced polygonal mirror, a rotary optical element, a screen mirror, and a scattering screen, wherein the collimating optical system is configured to change the shape of the light beam of the source and form it in accordance with further spreading to at least one amplitude modulator. The amplitude modulator is configured to change the brightness of the light beam passing through it. The scanning element includes at least one electro-optical polarizing element and is configured to pre-horizontally scan the light beam from the amplitude modulator by changing its polarization. The corrective optical system is configured to eliminate the distortion of the light beam that occurs when it passes through the scanning element. The improved polygonal mirror consists of an array of fixed micromirrors and is made with the possibility of a final horizontal scan of a beam of light passing through the correction system in the direction of the rotary mirror. The swivel mirror is configured to vertically scan the light beam and direct it to the screen mirror. The screen mirror is configured to reflect a beam of light at a desired point on the screen.

For the operation of the device, it is essential that the device contains a light source with a low Lagrange invariant selected from the group including, for example, a laser for monochrome images, one RGB laser, three monochrome primary color lasers, or other similar light sources.

For the operation of the device, it is important that the light source is configured to generate light of at least one color.

For the operation of the device, it is necessary that the collimating optical system contains at least one refractive or reflective element, configured to change the parameters and direction of the light beam.

For the functioning of the device, it is essential that the amplitude modulator is performed primarily on the basis of electro-optical elements or acousto-optical elements.

For the operation of the device, it is important that the amplitude modulator is configured to change the brightness of the light beam in accordance with the high-frequency signal that sets the image.

For the operation of the device, it is necessary that each electro-optical polarization element consist of one pair of controlled rotators of the plane of polarization, configured to change the direction of the plane of polarization of the light beam, and a birefringent medium, configured to deflect the light beam with orthogonal polarization.

For the functioning of the device, it is essential that N electro-optical polarizing elements are configured to receive 2 ^N positions of the light beam at the exit of the scanning element.

For the operation of the device, it is important that the positions of the light beam at the exit of the scanning element constitute a two-dimensional structure of horizontal rows arranged in a column.

For the functioning of the device, it is essential that the corrective optical system includes an array of micromirrors, microlenses, an array of DOE or similar elements necessary for aligning the parameters of light rays.

For the operation of the device, it is necessary that the corrective optical system includes a beam combiner configured to combine beams of different colors into one beam.

For the operation of the device, it is important that the beam combiner includes at least two dichroic mirrors, one blind mirror or other optical elements that perform the same functions.

For the operation of the device, it is essential that the advanced polygonal mirror is made with the possibility of vertical scanning of a light beam.

For the operation of the device, it is important that the screen mirror consist of many mini-mirrors, each of which would have a complex surface shape.

For the functioning of the device, it is essential that the scattering screen includes at least one lens, a shadow mask to increase the contrast ratio, an frosted glass optical element or other similar elements.

For the operation of the device, it is essential that the scattering screen includes at least one Fresnel lens.

For the operation of the device, it is important that the frosted glass element is made in the form of a frosted glass plate, frosted glass hemisphere array or other elements that perform the same functions.

For the functioning of the device, it is necessary that the number of positions of the light beam at the exit from the scanning element, constituting a two-dimensional structure, be equal to the number of micromirrors of the polygonal mirror.

For a better understanding of the present invention, the following is a detailed description thereof with corresponding drawings.

Figure 1 is a block diagram of a projection device made according to the invention.

Figure 2 is a diagram of a scanning element made according to the invention.

Figure 3 is a diagram of a polygonal mirror made according to the invention.

4 is a diagram of a screen mirror made according to the invention.

5 is a diagram of a scanning element, consisting of 11 electro-optical polarizing elements, and a view of the two-dimensional structure of the positions of the beam of light rejected by this scanning element.

Consider a specific embodiment of a projection device. In this embodiment, the projection device includes a light source 1, a collimating optical system, three amplitude modulators 2-4, three scanning elements 5-7, a correcting optical system, a polygonal mirror 8, a rotary optical element 9, a screen mirror 10 and a diffusing screen 11 The collimating optical system consists of a collimating lens 12, a first mirror 13, dichroic mirrors 14, 15, a second mirror 16 and three lenses 17-19.

Each of the scanning elements 5-7 consists of electro-optical polarizing elements, each of which includes one pair of controlled rotators 20 of the plane of polarization and a birefringent medium 21 (Figure 2). Corrective optical system consists of mirrors 22-24, acting as a combiner of rays. The polygonal mirror 25 consists of micromirrors 26 (Figure 3). The screen mirror 10 consists of many mini-mirrors 27.

In this embodiment of the projection device, each of the scanning elements consists of N = 11 electro-optical polarizing elements (Figure 5). Figure 5 shows a two-dimensional structure of the positions of a beam of light deflected by this scanning element. A two-dimensional structure may have 2 ^N beam positions. In this example, the two-dimensional structure contains 1920 positions of the output beam, which corresponds to the number of columns of the HDTV image.

In addition, the number of beam positions in the two-dimensional structure is equal to the number of micro-mirrors 26 of the polygonal mirror 25, and is also equal to the number of mini-mirrors 27 of the screen mirror 10.

The light source 1 emits a ray of light, which is collimated by a collimating lens 12 for further passage in the system, and then refracted by a mirror 13. A beam splitter, consisting of two dichroic mirrors 14, 15 and mirror 16, divides white light into three monochromatic rays of three main wavelengths . Each of the rays hits the input of one of the amplitude modulators 2-4, which change the brightness of the light beam in accordance with the control voltage applied to them, and project the rays onto the inputs of the scanning elements 5-7. Each of the scanning elements 5-7 carry out a preliminary horizontal scanning beam, namely the displacement of the beam in one of two positions ^{N-dimensional} structure corresponding to the position of the imaging pixel in the line image.

After passing through the scanning elements 5-7, the light rays are corrected by the elements of the corrective optical system and combined into one beam, which is projected onto the surface of the polygonal mirror 8. The polygonal mirror 8 performs the final horizontal scan of the beam, while transforming the position of the beam in a two-dimensional structure into a position in a one-dimensional structure , which is one horizontal row, after which the beam falls on a rotary optical element 9, which carries out a vertical scan of the beam by rotation Screen, the mirror 10, and the 27-screen minizerkalo mirror 10 reflects the beam falling on it in the desired position on the screen 11.

Although the above embodiment of the invention has been set forth to illustrate the present invention, it is clear to those skilled in the art that various modifications, additions and substitutions are possible without departing from the scope and meaning of the present invention disclosed in the attached claims.

Claims (24)

1. A projection device including a light source, a collimating optical system, at least one amplitude modulator, at least one scanning element, a correcting optical system, a polygon mirror, a rotary optical element, a screen mirror and a scattering screen, wherein the collimating the optical system is configured to change the shape of the light beam of the source and form it in accordance with further propagation to at least one amplitude modulator, wherein The tedious modulator is configured to change the brightness of the light beam passing through it, the scanning element includes at least one electro-optical polarizing element and is configured to pre-scan the light beam from the amplitude modulator by changing its polarization, the corrective optical system is made with the ability to eliminate the distortion of the light beam that occurs when it passes through the scanning element, the polygonal mirror consists of an array of micromirrors and is made with the possibility of the final horizontal scan of the light beam passing the correction system in the direction of the rotary mirror, the rotary mirror is configured to vertically scan the light beam and direct it to the screen mirror, the screen mirror is configured to reflect the light beam at the desired point on the screen. 2. The projection device according to claim 1, characterized in that the device comprises a light source with a low Lagrange invariant selected from the group including a laser for monochrome images, one RGB laser, and three monochrome primary colors. 3. The projection device according to claim 1, characterized in that the light source is configured to generate light of at least one color. 4. The projection device according to claim 1, characterized in that the collimating optical system contains at least one refractive or reflective element configured to change the parameters and direction of the light beam. 5. The projection device according to claim 1, characterized in that the amplitude modulator is made on the basis of electro-optical elements. 6. The projection device according to claim 1, characterized in that the amplitude modulator is based on acousto-optical elements. 7. The projection device according to claim 1, characterized in that the amplitude modulator is configured to change the brightness of the light beam in accordance with a high frequency signal that sets the image. 8. The projection device according to claim 1, characterized in that each electro-optical polarizing element consists of one pair of controlled rotators of the plane of polarization, configured to change the direction of the plane of polarization of the light beam, and a birefringent medium, configured to deflect the light beam with an orthogonal plane of polarization . 9. The projection device of claim 8, characterized in that N electro-optical polarizing elements are configured to receive 2 ^N positions of the light beam at the exit of the scanning element. 10. The projection device according to claim 9, characterized in that the positions of the light beam at the exit of the scanning element comprise a two-dimensional structure of horizontal rows arranged in a column. 11. The projection device according to claim 1, characterized in that the corrective optical system includes an array of micromirrors for aligning the parameters of light rays. 12. The projection device according to claim 1, characterized in that the corrective optical system includes an array of microlenses for aligning the parameters of the light rays. 13. The projection device according to claim 1, characterized in that the corrective optical system includes a DOE array for aligning the parameters of the light rays. 14. The projection device according to claim 1, characterized in that the corrective optical system includes a beam combiner configured to combine beams of various colors into one beam. 15. The projection device according to 14, characterized in that the beam combiner includes two dichroic mirrors, one dull mirror or other optical elements that perform the same functions. 16. The projection device according to claim 1, characterized in that the polygonal mirror is made with the possibility of the final horizontal scan of the light beam and the rearrangement of the beam positions from a two-dimensional structure located in a column of horizontal rows into a one-dimensional structure in the form of one horizontal row while maintaining the number of positions. 17. The projection device according to claim 1, characterized in that the screen mirror consists of many mini-mirrors. 18. The projection device according to claim 1, characterized in that the diffusing screen includes at least one shadow mask to increase the contrast ratio. 19. The projection device according to claim 1, characterized in that the scattering screen includes at least one Fresnel lens. 20. The projection device according to claim 1, characterized in that the scattering screen includes at least one lens. 21. The projection device according to claim 1, characterized in that the scattering screen includes at least one optical element made of frosted glass. 22. The projection device according to item 21, wherein the optical element is made of frosted glass in the form of a plate of frosted glass. 23. The projection device according to item 21, characterized in that the optical element is made of frosted glass in the form of an array of hemispheres of frosted glass. 24. The projection device according to claim 1, characterized in that the number of positions of the light beam at the exit of the scanning element constituting a two-dimensional structure is equal to the number of micromirrors of the polygonal mirror and the number of minirrors of the screen mirror.

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