KR20020062034A - Rotating Mirror Scanning for Micro display device - Google Patents

Abstract

PURPOSE: A rotating mirror scanning apparatus for use in a micro display is provided to realize a portable compact size and a high resolution for applying to a virtual reality. CONSTITUTION: A rotating mirror scanning apparatus for use in a micro display includes an LED array(110) for generating a line image, a rotating mirror(120) for reflecting by scanning the line image linearly output from the LED array(110), a magnifying lens(130) for magnifying and outputting the line image reflected from the rotating mirror(120) and a motor for operating the rotating mirror(120). The rotating mirror scanning apparatus has the advantage of increasing a resolution to a high level in comparison with an LCD, and of being a low power, a compact size and of preventing a user from being radiated from a deteriorate wave such as an infrared in comparison with a CRT.

Description

Rotating Mirror Scanning for Micro Display Device

The present invention relates to a rotating mirror scanning (RMS) device for a micro display, and more particularly, to a rotating mirror scanning device for a micro display capable of realizing a small size and high resolution virtual reality to be portable.

Currently, no company has succeeded in commercializing using Rotating Mirror Scsnning (RMS) devices worldwide.

RMS is expected to become a new and innovative technology among the conventional Microdisplay devices.

Similar to the prior art is Nintendo Co., Ltd., which was applied to a game machine using a pair of SLAs applied to a portable facsimile (FAX) by using a pair of scanning mirror arrays (SLAs) and a visual difference between both eyes.

The game machine developed by Nintendo is a 3D (Three-dimensional) game machine using virtual reality.

The term virtual reality refers collectively to seeing an artificial environment, especially a virtual environment created by a computer graphics system. One example is a virtual simulation device used to train an astronaut. As a display device, a virtual reality is realized by projecting a liquid crystal display (LCD) or a cathode ray tube (CRT).

A good example is that astronauts practice flying using virtual reality. A common device that provides virtual reality is HMD. You see. However, most of the shortcomings have been pointed out as low resolution, difficulty in implementing full color, and narrow viewing angle.

In addition, in the case of a liquid crystal display (LCD), the number of pixels is limited, so the resolution cannot be raised to a high level. In the case of a cathode ray tube (CRT), the weight is heavy, power consumption is high, and ultraviolet rays, electromagnetic waves, etc. There is a problem of emitting harmful harmful waves.

Disclosure of Invention An object of the present invention is to provide a rotating mirror scanning device for a micro display capable of realizing a compact and high resolution virtual reality to be portable, in view of the above-mentioned problems of the prior art.

In order to achieve the above object, a rotating mirror scanning device for a micro display according to the present invention includes an LED array for generating a linear line image, and a rotation for scanning and reflecting a linearly output line image through the LED array. It consists of a rotating mirror, a magnifying lens for enlarging and outputting a line image reflected from the rotating mirror, and a motor for driving the rotating mirror.

1 is a block diagram showing a pattern generator according to the present invention

2 shows a rotating mirror scanning device for a micro display according to the present invention;

FIG. 3 is a block diagram showing a circuit for driving the rotating mirror scanning device for a micro display shown in FIG.

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

110: LED array 120: rotating mirror

130: enlarged magnified lens

Hereinafter, a configuration and an operation according to an exemplary embodiment of the present invention will be described with reference to the accompanying drawings.

1 is a block diagram showing a pattern generator according to the present invention.

As shown in FIG. 1, the pattern generator according to the present invention generates a linear image according to information input from the pattern generator 100, and the emission time of the LED array 40 is determined by the pattern generator ( 100).

The pattern generator 100 includes a microcomputer 80, a keypad 90, a memory unit 10, a graphics processor 20, an LED array driver 30, and a clock generator 50.

Here, the keypad 90 is for externally inputting necessary information, for example, a resolution, a resonance frequency, and the like of a linear display device (Scanning Liner Array, hereinafter abbreviated as SLA) to be tested. It is for storing necessary information, for example, an image to be measured. At this time, since a standard image suitable for each is required according to the specification of the SLA to be measured, the memory unit 10 stores standard screens meeting various SLA specifications.

The memory unit 10 includes a test pattern ROM 11 storing an image to be expressed, a ROM memory 14 storing basic operating system functions of the pattern generator 100, and a pattern. The RAM memory 13 temporarily stores the operation of the generator 100 and the video memory 12 supporting the image related operation of the pattern generator 100.

The graphic processor 20 supplies an image signal, a synchronization signal, and the like to the LED array driver 30 so that the LED array 40 emits a linear image.

And the microcomputer 80 is to control each element of the pattern generator 100 as a whole.

In the specific operation of the pattern generator, the pattern generator 100 first checks whether the vibration of the scanner 70 is stable. To this end, the microcomputer 80 of the pattern generator 100 measures the time between the pulses output from the scanner 70 for a predetermined time and checks whether the deviation is input below a predetermined value.

When it is confirmed that the vibration of the scanner 70 is stable, the scanning frequency is determined based on the period measured in the checking process. The scanning frequency is the same as how many frames are composed of one second. In the case of a commercially available resonant scanner that can be applied to an SLA, the resonance frequency is 60 Hz, and thus 60 frames of an image can be displayed in one second. However, since the mirror movement changes in direction every time, the output order of the raster image has to be changed every time. In most cases, only one cycle of two scanning outputs image data.

The pattern generator 100 implements an image using the initially measured scanning frequency and resolution data previously input through the keypad 90. If the scanning cycle is 60 Hz, 30 frames per second, and the resolution in the perpendicular direction of the scanner is 100 dots, the image data is output for the first 1/30 seconds and nothing for the next 1/30 seconds. Wait for the mirror to return to its place. In addition, in order to configure one frame having a resolution of 100 dots, the linear image is updated 100 times in 1/30 second to realize a complete image.

In order to implement such a process, it is necessary to accurately measure the resonance frequency of the scanner and generate a frame period and a line period based on the frequency. The frame period and the line period are variable with high accuracy as shown in FIG. The clock signal output from the clock generator 50 is synchronized.

In the manner described above, a synchronization signal is generated which is applied to a scanner having an arbitrary frequency.

4 is a view showing a rotating mirror scanning (rms) device for a micro display according to the present invention.

Rotating Mirror Scanning (RMS) device for micro display according to the present invention is a micro display that realizes micro display and is portable using not only game machine but also HMD (Head Mounted Display) system. It can also be applied to visible models.

That is, the present invention provides an LED array 110 for generating a linear line image, a rotating mirror 120 for scanning and reflecting a linearly output line image through the LED array, and the rotein. It is composed of a magnifying lens (130) for enlarging and outputting the line image reflected from the setting mirror 120. In this case, the magnifying lens 130 may be configured as a microlens to reduce the overall size of the product. The source of the line image is a signal transmitted together with a TV video signal and a video signal.

The present invention can realize virtual reality in two dimensions (2D) or three dimensions (3D) by using a compact, low-resolution portable mirror rotating mirror scanning device using an RMS device. have.

In the pattern generator 100 according to the present invention, an image source may be a signal source from the LED array 110. An input signal generated from the LED array 110 may be an image through a rotating mirror 120. By sequentially scanning the circles, frames are sequentially formed on the mirror. At this time, the rotating mirror 120 is driven through a motor. The screen scanned by the rotating mirror 120 is then magnified through a magnifying lens 120 and displayed in the air by a predetermined distance.

At this time, if a display designed to be 60 frames per second is implemented as a general LED, the cost increases because a much larger number of LEDs must be implemented as a 1: 1 than the scanned one, but the rotating mirror 120 is random in structure. Because the rotational movement is made about the axis of, the angle of reflection of the mirror changes nonlinearly as the axis rotates.

In addition, the linear image from the LED array 110 causes screen distortion due to nonlinear error due to the nonlinear change of the rotating mirror 120. Therefore, it is necessary to adjust the emission time of the LED array 110 to match the characteristics of each scanner.

FIG. 5 is a block diagram showing a circuit for driving the rotating mirror scanning device for a micro display shown in FIG.

If the present invention is applied in three dimensions (3D), the LED light source generated in a linear (Liner) is transmitted to the beam splitter (not shown), the left and right are separated by both sides by the beam splitter, separated LED Scanning the light source sequentially with rotating mirrors (each configured) can also create a structure that enters the left and right eyes. In this case, the image generated from the image source may be a television image signal or a video signal as described above, and the present invention may be input through an optical fiber (not shown) in accordance with the LED linear signal. have.

The LED array 110 may represent a linear one-dimensional image in a structure in which fine LEDs are linearly arranged. In order to construct a two-dimensional screen, a driver circuit that can accurately control this is essential. The LED array 110, the rotating mirror 120, and the drivers are the key components of the RMS.

The information to be displayed first is stored in a data store device, and depending on the application, data storage can be in ROM, PROM, EPROM, EEPROM and Flash memory. Memory) and RAM.

In addition, depending on the user, a memory device may be selected when only reading data (ROM) and reading, writing, and modifying (RAM). The data input to the data storage unit 210 is sequentially controlled and read by the timing and control circuit 260, and shifts the data to the shift register 220 under the control of the timing controller 260. Shift register 220 is, for example, each 256 LED bits position.

At this time, the vibration of the rotating mirror 120 is controlled by the mirror drive circuit and is generally driven by a sinusoidal signal to avoid sudden movement of the mirror. In order to maintain a clear resolution, it is important to consider when constructing a circuit to repeatedly scan a point at exactly the same position when scanning.

The shift register 220, the latch 230, and the LED circuit 240 may be configured as a part of a circuit board, and the two-dimensional mirror driving circuit unit 250 may be an optical scanner. The timing controller 260 may be a programmable microprocessor (MPU). All of the display of this information is screened by two-dimensional (X, Y) scanning using a point LED.

The present invention as described above has the following effects.

First, compact and high resolution virtual reality can be implemented to be portable.

Second, compared to a liquid crystal display device (LCD), the resolution can be raised to a high level, and compared to a cathode ray tube (CRT), there is an effect of preventing harmful waves such as low power consumption, light weight, ultraviolet rays, and electromagnetic waves harmful to a human body.

Claims (1)

An array of LEDs generating linear line images, A rotating mirror which scans and reflects a line image linearly output through the LED array; A magnifying lens configured to enlarge and output the line image reflected by the rotating mirror; Rotating mirror scanning device for a micro display, characterized in that consisting of a motor for driving the rotating mirror.