KR100512398B1 - Reflection Type Display Apparatus - Google Patents

Abstract

The present invention relates to a reflective display device, and more particularly, three primary colors (RGB) separated from predetermined N micro mirror surfaces driven by an actuator driven by a three-wavelength light source are reflected and projected by a rotating polygon mirror surface again. The present invention relates to a reflective display device in which an image is formed on a screen.

Means for achieving the present invention, a three-wavelength light source consisting of red, green, blue; A first opening through which the three wavelength light passes; A focusing lens portion for causing the image of the first opening to reflect and pass through the diffraction grating mirror; Predetermined N diffraction grating micromirrors driven by an actuator and reflecting an incident image; A rotating polygonal mirror in which red, green, and blue three-wavelength light separated from the micromirror surface are reflected again and projected on the screen; A second opening through which an image of the first opening separated in color is transmitted; And a projection lens part projected onto the projection screen.

Description

Reflective Display Apparatus {Reflection Type Display Apparatus}

The present invention relates to a reflective display device, and more particularly, three primary colors (RGB) separated from predetermined N micro mirror surfaces driven by an actuator driven by a three-wavelength light source are reflected and projected by a rotating polygon mirror surface again. The present invention relates to a reflective display device in which an image is formed on a screen.

In general, the reflective projection display device has higher light efficiency than other display devices such as LCDs. Currently, reflective display devices developed by MEMS (Micro electro-mechanical systems) technology uses three color filters for color tuning, which makes the optical system complicated. Examples of reflective projection display devices include a digital micromirror device (DMD) method, a thin film micro-mirror array (TMA) method, and a grating light valve (GLV) method. DMD is a digital electrostatic driving method of micro mirror array, developed by Texas Instruments (TI). Thin film micro-mirror array (TMA) is a method of driving analog actuators of micro mirror arrays, and the original patents are owned by Aura and Daewoo Electronics of the United States. The GLV method was developed by SLM and uses a diffraction grating.

However, the conventional reflective projection display method has a disadvantage in that the system is complicated and bulky since the three-plate type drive type has a drive module mainly for RGB three primary colors. In addition, since M x N (M, N is a natural number) is integrated into the reflective driving device and the semiconductor device, a large number of defects are generated in the pixel, thereby reducing productivity.

Accordingly, the present invention has been made to solve the above problems, and is a single-plate drive type integrated into one drive module for three primary colors, consisting of N drive elements instead of MxN, and having a small volume and a simple system. Its purpose is to develop a display device with fewer defects.

Means for achieving the present invention, a three-wavelength light source consisting of red, green, blue; A first opening through which the three wavelength light passes; A focusing lens portion for causing the image of the first opening to reflect and pass through the diffraction grating mirror; Predetermined N diffraction grating micromirrors driven by an actuator and reflecting an incident image; A rotating polygonal mirror in which red, green, and blue three-wavelength light separated from the micromirror surface are reflected again and projected on the screen; A second opening through which an image of the first opening separated in color is transmitted; And a projection lens part projected onto the projection screen.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. 1 is a block diagram showing an example of a system configuration for a reflective display device according to the present invention.

Referring to FIG. 1, light emitted from a three-wavelength light source 110, such as a laser diode, passes through a primary slit or opening 171 and is incident on the diffraction grating array 100 after reflection by the first reflection mirror 130. First, each grid of lines is driven at any one of the three color angles so that light corresponding to the color is projected through the opening 172. By adjusting the angle of one mirror, the amount of light transmitted through the aperture is controlled, and the time of one actuator is driven to realize the brightness of the color. The projected light reflects the second mirror and reflects the rotated polygon mirror 160 again, and then the video is implemented on the screen.

2 is a diagram of a driven diffraction grating array fabricated on a silicon substrate 104. It can be seen that N mirror surfaces (N is a natural number) are made of a diffraction grating. The mirror surface consists of a diffraction grating divided into three parts for red, blue and green. In addition, an electrode line 102 for driving the diffraction grating array is adhered to the electrode connection pad 103 with the driving circuit.

3 is a cross-sectional view cut along the plane Aa of the driven diffraction grating array. If the surface of the mirror 200 is made of blaze, the diffraction efficiency is maximized, and any angle ( Blaze, which has the maximum diffraction efficiency for one wavelength λ, is manufactured in three parts for red, blue, and green for three colors by the microfabrication process. The light incident from the three wavelength light source 110 is made so that the three colors are divided at different angles when reflected from the surface of the blaze. The principle is clearly shown in the following diffraction grating equation.

.

Where m is an integer, a is a lattice spacing, θ i is an incident angle, and θ m is a diffraction angle.

If the blaze is manufactured to satisfy the following equation, it has the maximum diffraction efficiency.

Where φ is the angle of inclination.

Below the mirror surface is an actuator 201 made with MEMS technology. The actuator 201 is a cantilever beam made of a piezoelectric material Pb (Zr, Ti) O 3.

Fig. 4 shows a phenomenon in which the light of color separation three wavelengths after the actuator is driven is scanned through the opening. First, light of one color is scanned from a diffraction grating array of one line to form a line of pixels on the screen, and then the pixels of the line are formed on a screen by a rotating polygon mirror. That is, the brightness for each pixel consists of fine angle division and time division.

For example, for a 640x480 resolution display, there are 640 driven diffraction gratings in one row and the size of the mirror for the diffraction grating is 50 micrometers in either horizontal or vertical. First, the angle is adjusted by the actuator under the mirror so that the blue signal for one pixel passes through the opening, and the brightness is adjusted to the time of staying at the minute angle and the position of the angle. At the same time, the brightness of the adjacent pixels is adjusted by the same principle. A line of signals is simultaneously formed on the projection screen, and the signals of the next line are reflected from the rotated polygonal mirror plane to the projection screen by the same principle. When 480 lines are projected, a blue screen is formed.

The following is the signal transmission process for green. First, the angle is adjusted by the actuator under the mirror so that the green signal for one pixel passes through the opening, and the brightness is adjusted to the time of staying at the minute angle and the position of the angle among the angles. Similarly, information about one screen of green is transmitted to the projection screen.

The following is the signal transmission process for red color. First, the angle is adjusted by the actuator under the mirror so that the green signal for one pixel passes through the opening, and the brightness is adjusted to the time of staying at the minute angle and the position of the angle among the angles. Similarly, information about one screen of red is transmitted to the projection screen to form a screen embodied in color.

Another embodiment of the invention. Instead of a single mirror, a line of red diffraction gratings, a line of green diffraction gratings, and a line of blue diffraction gratings are manufactured on one silicon substrate instead of a single mirror. The driving is driven by piezoelectric or electrostatic. When driven by a piezoelectric body, the phase of the stop forms a pixel and the brightness is adjusted by the driving angle. When driven by static electricity, the driving angle is set to one of R, G, and B, and the brightness is adjusted by the number of on / off driving.

One line of red diffraction grating array, one line of green diffraction grating array, and one line of blue diffraction grating array are driven simultaneously so that the optical system is configured so that the mirrors are lined up on the screen through the polygon mirror or driving mirror. The next line also mirrors the screen in the same way. In the same way, the image of the bottom row of mirrors forms on the screen and a screen is completed within 33.3 msec.

As described above, in the present invention, the three primary colors (RGB) separated from the micromirror surface, which is a predetermined N diffraction grating, in which light from the three-wavelength light source is driven by an actuator, are reflected by a rotating polygonal mirror surface and imaged on the projection screen. Is formed.

Since the diffraction grating is a linear device, the system is simple and the device defects can be greatly reduced, thereby improving productivity. Therefore, single-panel display is possible by using small devices, and it can be applied to portable displays such as mobile phones and PDAs.

1 is a block diagram of a reflective display device according to the present invention;

2 is a plan view of a plurality of actuator-type diffraction gratings according to the present invention;

Figure 3 is a cross-sectional view cut along the A-a plane of a single actuator type diffraction grating according to the present invention

4 is a cross-sectional view taken along the plane A-a of FIG. 2 according to the present invention;

* Description of the symbols for the main parts of the drawings *

100: diffraction grating 110: three wavelength light source

120: focusing lens 130: first reflection mirror

140 projection lens 150 second reflecting mirror

160: polygon mirror 171: first opening

172: second opening

Claims (3)

A three wavelength light source 110 composed of red, green, and blue; A first opening 171 through which the three wavelength light passes; A second opening 172 through which an image of the first opening 171 which has been separated in color is transmitted; A focusing lens unit (120) for allowing an image of the first opening (171) to reflect a diffraction grating mirror and to pass through the second opening (172); A predetermined diffraction grating micromirror 100 which is driven by an actuator and reflects an incident image; A rotating polygon mirror 160 which red, green, and blue three-wavelength light separated from the surface of the micromirror 100 are reflected again and projected on the screen; And Projection type display device, characterized in that it comprises a projection lens unit 140 projected on the projection screen. The method of claim 1, wherein the micro-mirror 100 is divided into three parts per mirror for a plurality of mirrors to project tricolor light such as red, blue, green, etc., characterized in that the mirror surface is composed of an uneven surface or a blaze Projective display device. The projection display device according to claim 1, wherein the micro mirror (100) has a diffraction grating type and has a three-row projection method for a plurality of reds, a plurality of blues, and a plurality of greens.