KR20110017666A - Laser display system - Google Patents

Abstract

PURPOSE: A laser display system is provided to reduce the size of an optical system by arranging a distortion correcting element with at least two transmitting sides and at least one reflecting side in a transmitting system. CONSTITUTION: A laser display system includes optical source, a color synthesizing system, an optical scanner(20), and a distortion correcting element. The optical source generates red light, green light, and blue light. The color synthesizing system synthesizes the red light, the green light, and the blue light. The optical scanner scans the synthesized light. The distortion correcting element corrects the distortion of the scanned light and outputs the corrected light to the outside.

Description

Laser display system

The present invention relates to a laser display system, and more particularly to a laser display system having optical means for correcting distortion.

In general, along with the rapid advancement into the multimedia society, large-sized and high-definition display screens are required, and in recent years, in addition to high resolution, the implementation of natural natural colors is important.

In order to achieve a perfect natural color, it is necessary to use a light source with high color purity, such as a laser. One of the systems for implementing an image using a laser is a display system using an optical scanner.

Display systems, such as laser projectors and laser projections, are systems that display images by projecting input image signals onto a screen using laser light emitted from a laser light source.These are mainly used for presentations in conference rooms and movie projectors in theaters. It is used to implement a home theater in the home, and the like.

A display system using a general optical scanner may include a laser light source, a light modulator, an optical system, an optical scanner, an image controller, and the like.

Here, the laser light source includes a red laser that generates red light, a green laser that generates green light, and a blue laser that generates blue light.

The laser light source emits the generated laser light to the light modulator, and the light modulator modulates the incident laser light according to the image control signal of the image controller to generate diffracted light and emit the light to the optical system.

Subsequently, the generated diffracted light is transmitted to the optical scanner through an optical system, and the optical scanner scans the light while rotating the mirrors at a predetermined angle according to the mirror control signal of the image controller to display an image.

SUMMARY OF THE INVENTION An object of the present invention is to arrange a distortion correction element having at least two transmission surfaces and at least one reflection surface in a projection system, thereby reducing the size of the distortion correction element, thereby reducing the size of the entire optical system and removing the distortion phenomenon. It is to provide a display system.

Technical problems to be achieved by the present invention are not limited to the above-mentioned technical problems, and other technical problems not mentioned above are clearly understood by those skilled in the art from the following descriptions. Could be.

The laser display system according to the present invention includes a light source for generating red light, green light, and blue light, a color synthesis system for synthesizing red light, green light, and blue light, an optical scanner for scanning the synthesized light, and a distortion of the scanned light. At least one reflective surface for reflecting light incident from the color synthesizing system to the optical scanner so as to be emitted to the outside, and at least one light transmissive light being positioned on a path of light exiting through the optical scanner to the outside through the optical scanner It may be configured to include a distortion correction element having two transmission surfaces.

Here, the distortion correction element includes a first transmission surface for transmitting the light incident from the color synthesis system, a reflection surface for reflecting the light transmitted through the first transmission surface to the optical scanner, and a second transmission for the light reflected from the optical scanner. And a third transmission surface facing the second transmission surface and transmitting the light transmitted from the second transmission surface.

In addition, the distortion correction element includes a first reflecting surface for reflecting light incident from the color synthesis system, a second reflecting surface for reflecting light reflected from the first reflecting surface to the optical scanner, and a light reflecting light transmitted from the optical scanner. It may comprise a first transmission surface and a second transmission surface facing the first transmission surface and transmitting light transmitted from the second transmission surface.

The reflection surface of the distortion correction element may be coated with a mirror, and the anti-reflection (AR) film may be coated on the transmission surface of the distortion correction element.

Next, the distance between the optical scanner and the distortion correction element has a maximum value when the path of the light reflected by the optical scanner is located at the boundary of the reflection surface of the distortion correction element, and the path of the light reflected by the reflection surface of the distortion correction element is It may have a minimum value when located at the boundary of the reflective surface of the optical scanner.

The transmission surface of the distortion compensating element may be an inclined surface that gradually approaches the optical scanner from the top to the bottom of the transmission surface.

Other objects, features and advantages of the invention will become apparent from the following detailed description of embodiments taken in conjunction with the accompanying drawings.

The laser display system according to the present invention has the following effects.

Since the present invention uses a distortion correction element having at least two transmission surfaces and at least one reflection surface, the distance between the optical scanner and the distortion correction element can be shortened, thereby reducing the size of the distortion correction element, The size of the whole optical system can be reduced.

In addition, the present invention can reduce the distortion of the optical scanner by using a small distortion correction element, it can be suitably applied to the projector module embedded in a portable device such as a digital camera, a mobile phone.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a view showing a laser display system according to the present invention. As shown in FIG. 1, a light source 11, an optical scanner 19, a collimator 13, a color combining system 15, a mirror 17, It may be configured to include the distortion correction element (21).

Here, the light source 11 is comprised from the red laser light source 11a which produces red light, the green laser light source 11b which produces green light, and the blue laser light source 11c which produces blue light.

The first collimator 13a is positioned in front of the red laser light source 11a, the second collimator 13b is positioned in front of the green laser light source 11b, and the third collimator 13b is located in front of the blue laser light source 11c. The collimator 13c may be located.

Here, the collimator 13 may serve to bring the laser light closer to parallel or substantially parallel to have a minimum spot size on the screen.

The color synthesizing system 15 then proceeds by synthesizing the red, green and blue light on a single optical path, and the mirror 17 between the color synthesizing system 15 and the optical scanner 19 to facilitate the photomechanical arrangement. Can be placed on.

In addition, the distortion compensating element 21 may be disposed between the optical scanner 19 and the screen 23 to reduce the distortion occurring in the screen 23.

Here, the distortion correction element 21 is formed in the form of a thinner than the thickness of the lower region of the upper region when viewed from the side.

In general, since the optical path distance between the optical scanner 19 and the screen 23 moves away from the center area of the screen to the edge area, the screen displayed on the screen 23 is a pin-cushion that bends toward the center of the screen. Distortion phenomenon appears.

Therefore, in order to correct this distortion phenomenon, it is possible to solve by disposing the distortion correction element 21 between the optical scanner 19 and the screen 23.

Since the distortion compensating element 21 is formed from the side, the thickness of the upper region is thinner than the thickness of the lower region, so that the optical path distance between the optical scanner 19 and the center region of the screen 23 and the optical scanner The difference in the optical path distance between the area 19 and the edge of the screen 23 can be compensated for, so that the distortion phenomenon can be corrected.

Therefore, the distortion correction element 21 can be reduced in size as it is disposed closer to the optical scanner 19, and the size should be larger as it is arranged in the vicinity of the screen 23. As shown in FIG.

As described above, since the distortion correction element 21 is disposed as close to the optical scanner 19 as possible, the size of the distortion correction element 21 may be reduced, thereby reducing the size of the overall optical system.

However, in the laser display system as shown in FIG. 1, in order to avoid interference between the light from the illumination system including the light source 11 and the mirror 17, the distortion correction element 21 must be disposed away from the optical scanner 19. The size of the distortion compensating element 21 may be increased to increase the height of the entire optical system.

Therefore, in the present invention, the distortion correction element 21 can be disposed as close as possible to the optical scanner 19, and the distortion correction element 21 can be newly processed so that the size of the distortion correction element 21 can be reduced. .

That is, the present invention removes the mirror 17 between the color synthesizing system 15 and the optical scanner 19 and forms a mirror surface on the distortion correction element 21, thereby providing the distortion correction element 21 with the optical scanner 19. ) Can be arranged as close as possible, and the size of the distortion correction element 21 can be reduced.

The distortion correction element 21 of the present invention includes at least one reflective surface for reflecting the light incident from the color synthesizing system 15 to the optical scanner 19 so as to correct the distortion of the scanned light and output it to the outside. Light incident from 15 may be processed to have at least two transmission surfaces positioned on the path of the light exiting through the optical scanner 19 to transmit light.

2 is a side view illustrating an arrangement and an optical path of an optical scanner and a distortion correction device according to a first embodiment of the present invention, and FIG. 3 illustrates an arrangement and an optical path of an optical scanner and a distortion correction element according to a first embodiment of the present invention. It is a perspective view showing.

As shown in Figs. 2 and 3, the distortion correction element 30 is formed to have a first, second, third transmission surface and one reflection surface.

Here, the first transmission surface transmits light incident from the color synthesizing system, and the reflection surface reflects the light transmitted through the first transmission surface to the scan mirror 22 of the optical scanner 20.

The second transmission surface transmits the light reflected from the scan mirror 22 of the optical scanner 20, and the third transmission surface faces the second transmission surface and transmits the light transmitted from the second transmission surface. .

Here, the reflective surface of the distortion correction element 30 may be coated with a mirror.

In this case, the reflection surface of the distortion correction element 30 may be manufactured in one piece, or may be manufactured separately by separating only the reflection surface.

The AR, anti-reflection (AR) film may be coated on the first, second, and third transmission surfaces of the distortion compensating element 30 so that light loss does not occur.

Subsequently, the distortion correction device 30 may be manufactured using transparent glass or transparent plastic.

On the other hand, the mirror surface of the distortion correction element 30 is formed so that the incident optical axis and the optical axis reflected by the mirror surface are perpendicular to each other.

In addition, the mirror surface of the distortion correction element 30 may be located at the lower end of the distortion correction element 30 so as not to be located on the path of the light incident from the optical scanner 20.

The distance between the optical scanner 20 and the distortion correction element 30 has a maximum value when the path of the light reflected by the optical scanner 20 is located at the boundary surface of the reflection surface of the distortion correction element 30, and the distortion correction is performed. The path of the light reflected by the reflective surface of the device 30 may have a minimum value when it is located at the boundary of the reflective surface of the optical scanner 20.

Next, the transmission surface of the distortion correction element 30 has an inclined surface gradually closer to the optical scanner 20 from the top to the bottom of the transmission surface.

That is, the distortion correction element 21 is formed in a shape in which the thickness of the upper region is thinner than the thickness of the lower region, so that the distance between the optical path 19 between the optical scanner 19 and the center region of the screen 23 is reduced. The difference in the optical path distance between the optical scanner 19 and the edge area of the screen 23 can be compensated for, so that the distortion phenomenon can be corrected.

4 is a perspective view illustrating an arrangement and an optical path of an optical scanner and a distortion correction device according to a second exemplary embodiment of the present invention.

As shown in FIG. 4, the distortion correction element 30 is formed to have first and second transmission surfaces and first and second reflection surfaces.

Here, the first reflecting surface reflects light incident from the color synthesis system, and the second reflecting surface reflects the light reflected from the first reflecting surface to the scan mirror 22 of the optical scanner 20.

The first transmission surface transmits the light reflected from the scan mirror 22 of the optical scanner 20, and the second transmission surface faces the first transmission surface and transmits the light transmitted from the second transmission surface. .

Here, the first and second reflective surfaces of the distortion correction element 30 may be coated with a mirror.

In this case, the first and second reflective surfaces of the distortion compensating element 30 may be manufactured in one piece, or may be manufactured in a separate type by separating the reflective surfaces separately.

In addition, an AR (anti-reflection) film may be coated on the first and second transmission surfaces of the distortion compensating element 30 so that light loss does not occur.

As described above, the distortion correction device 30 according to the present invention includes at least one reflective surface for reflecting light incident from the color synthesis system to the optical scanner, and a path of light from which the light incident from the color synthesis system exits through the optical scanner. Since it is formed to have at least two transmissive surfaces positioned on and transmitting light, it is possible to remove elements such as mirrors from the optical system, thereby reducing the size of the optical system.

By removing the mirror and forming the reflection surface on the distortion correction element 30 instead of the mirror, the distortion correction element can be disposed close to the optical scanner, thereby further reducing the size of the distortion correction element.

In addition, the distortion correction device of the present invention has the effect of reducing the distortion phenomenon, such as the pin-cushion of the center of the screen is bent.

5 is a view comparing screen pixels of a screen using the distortion correction device and screen pixels of the screen without using the distortion correction device according to the present invention.

As shown in FIG. 5, when the screen is displayed on the screen by default without using the distortion correction device of the present invention, the screen may be distorted along the X axis from the edge of the screen toward the center region.

On the other hand, when the screen is displayed on the screen using the distortion correction device of the present invention, it can be seen that the screen is uniformly and uniformly displayed from the edge of the screen toward the center area along the X axis to compensate for the distortion.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention. Therefore, the technical scope of the present invention should not be limited to the contents described in the embodiments, but should be defined by the claims.

1 shows a laser display system according to the invention.

2 is a side view showing an arrangement and an optical path of an optical scanner and a distortion correction device according to a first embodiment of the present invention;

3 is a perspective view showing an arrangement and an optical path of an optical scanner and a distortion correction device according to a first embodiment of the present invention;

4 is a perspective view showing an arrangement and an optical path of an optical scanner and a distortion correction device according to a second embodiment of the present invention;

5 is a view comparing screen pixels of the screen using the distortion correction device and screen pixels of the screen without using the distortion correction device according to the present invention.

Claims (10)

A light source for generating red light, green light, and blue light; A color synthesis system for synthesizing the red light, the green light, and the blue light; An optical scanner for scanning the synthesized light; And, At least one reflective surface for reflecting light incident from the color synthesizing system to the optical scanner so as to correct distortion of the scanned light and outputting it to the outside, and light incident from the color synthesizing system is emitted to the outside via the optical scanner And a distortion correction element having at least two transmission surfaces positioned on a path of light to transmit the light. The method of claim 1, wherein the distortion correction device, A first transmission surface through which light incident from the color synthesis system is transmitted; A reflection surface for reflecting light transmitted through the first transmission surface to the optical scanner; A second transmission surface for transmitting the light reflected from the optical scanner; And a third transmission surface facing the second transmission surface and transmitting the light transmitted from the second transmission surface. The method of claim 1, wherein the distortion correction device, A first reflecting surface reflecting light incident from the color synthesizing system; A second reflecting surface reflecting light reflected from the first reflecting surface to the optical scanner; A first transmission surface for transmitting the light reflected from the optical scanner; And a second transmission surface facing the first transmission surface and transmitting the light transmitted from the second transmission surface. The laser display system of claim 1, wherein the reflection surface of the distortion correction element is coated with a mirror. The laser display system of claim 1, wherein the transmission surface of the distortion compensator is coated with an anti-reflection film. The laser display system of claim 1, wherein the distortion correction device is transparent glass or transparent plastic. The laser display system according to claim 1, wherein the optical axis incident on the mirror surface and the optical axis reflected by the mirror surface are perpendicular. The distortion correction device according to claim 1, wherein the distance between the optical scanner and the distortion correction element has a maximum value when the path of the light reflected by the optical scanner is located at the boundary of the reflection surface of the distortion correction element. And the path of light reflected by the reflective surface of the laser beam has a minimum value when it is located at the boundary of the reflective surface of the optical scanner. The laser display system according to claim 1, wherein the transmission surface of the distortion correction element is an inclined surface gradually closer to the optical scanner from the top to the bottom of the transmission surface. The laser display system of claim 1, wherein a collimator is arranged between the light source and the color synthesis system to make the light generated by the light source in parallel.

Images