KR20030040802A - Apparatus for laser diode optic module of laser system - Google Patents

Abstract

PURPOSE: A laser diode optical module apparatus is provided to express an image with a low laser power without loss of beams from a laser diode by adjusting a strength of an input current of a power supply and modulating an output of the laser diode. CONSTITUTION: A signal processing part(21,22) separates RGB signals from an input image signal. A current modulation part(23) adjusts a current strength of each RGB signal from the signal processing part according to a gray level to be expressed. A power part(24) generates RGB powers proportional to the RGB currents from the current modulation part. A laser light source generates RGB beams proportional to the RGB powers. A scanning part(28) scans the RGB beams in vertical and horizontal directions and constructs an image on a screen.

Description

Apparatus for laser diode optic module of laser system

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a laser system, and more particularly, to an LD optical module device of a laser system that modulates an output of an LD by adjusting a current of a power supply for supplying power to a laser diode (LD).

In general, a laser scanning system adjusts the amount of light in a beam by injecting light from R, G, and B laser light sources into each modulator (acoustic light modulator (AOM) or electric light modulator (EOM)).

In other words, the laser scanning system modulates a beam by inserting light from an R, G, or B laser into a modulator (AOM or EOM), and then uses a scanner to produce a two-dimensional image on a screen. Most of the lasers used in this case are continuous waves (CW), which are lasers that emit light continuously.

1 is a block diagram of a general laser scanning system, which includes a laser, a modulator, and a scanner.

1, the R, G, B laser diodes (LD) 11 are supplied with power from the power supply unit 19, and the beams from the R, G, B LDs 11 are each optical modulators. (AOM or EOM) 12 is incident. The intensity of the beam incident on the optical modulator 12 is adjusted according to the image signal. That is, adjusting the intensity of the beam according to an image signal, for example, a gray level to be implemented, is called light modulation.

The modulated R, G, and B beams are gathered into the galvanometer 16 through the mirrors 13 to 15 in pixel units, respectively. The incident beam is scanned in the longitudinal direction of the image by the galvanometer 16 and again by the polygon mirror 17 in the horizontal direction of the image to produce the image on the screen 18.

However, the method of modulating the light using the AOM or the EOM described above is used to adjust or grate the intensity of the beam irradiated to the scanner by the refractive index of the AOM or the EOM using a sound wave. ) To achieve gray scale according to the angle of the beam irradiated to the scanner. This is an inefficient way of wasting the beam by constantly irradiating a laser of constant power regardless of the dark and light of the image actually on the screen. In other words, the energy from the laser in black represents the same amount of energy used to produce white, and the modulator throws away all of the light. Then what's actually on screen is black, which is nothing.

This is not only the scan system illustrated in FIG. 1, but also a system using a light valve such as a grating light value (GLV), a liquid crystal display (LCD), a digital micromirror display (DMD), and the like. Implement

The present invention is to solve the above problems, an object of the present invention is to modulate the output of the LD by adjusting the intensity of the input current of the power supply for supplying power to the LD, thereby lowering the laser beam without loss of the LD An LD optical module device of a laser system for representing an image in power is provided.

It is another object of the present invention to provide an LD optical module device of a laser system that extends the life of LD by detecting the output power of the LD through a feedback system and adjusting the intensity of the input current of the power supply.

1 is a configuration diagram of a general laser system

2 is a block diagram of an LD optical module device of a laser system according to the present invention;

3 is a view showing an output power modulation process of the LD by adjusting the current strength of the present invention

4 is a diagram illustrating an example of implementing gray levels by modularizing the output power of LD through the current strength of the present invention.

5 is a configuration diagram of a laser system to which the LD optical module device according to the present invention is applied

Explanation of symbols for main parts of the drawings

21: R, G, B separation unit 22: A / D conversion unit

23: CHM unit 24: power unit

25: feedback unit 26: H, V separation unit

27: LD28: scanning system

LD optical module device of the laser system according to the present invention for achieving the above object, the signal processing unit for separating and digitizing the R, G, B signal from the input image signal, and the R, G output from the signal processing unit A current modulator for adjusting the current intensity of each B signal according to a gray level, a power unit for generating and outputting R, G, and B powers proportional to the R, G, and B currents output from the current modulator; And scanning a laser light source emitting R, G, B beams proportional to the R, G, B powers output from the power unit, and the R, G, B beams emitted from the laser light source in a vertical direction and a horizontal direction. And a scanning unit constituting an image on the screen.

The apparatus may further include a feedback unit which detects the intensity of the beam output from the laser light source and feeds back the current modulator as a current correction signal.

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

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

FIG. 2 is a block diagram illustrating an LD optical module device of a laser system according to the present invention, in which R, G, and B light amounts output from an LD are adjusted by adjusting a current input to a power supply.

2, an R, G, and B separation unit 21 for separating R, G, and B from an image signal, an A / D conversion unit 22 for digitizing the separated R, G, and B signals, respectively, R, G and B currents output from the current height modulation (CHM) unit 23 and the CHM unit 23 to adjust the current strength of the digitized R, G, B signal according to the gray level to be implemented. A scanning system that emits R, G, and B beams in proportion to R, G, and B powers, and generates R, G, and B powers in proportion to R, G, and B powers. R, G, B LD (27) output to (28), feedback unit 25 for detecting the power of the R, G, B beams output from the LD (27) and feeds back to the CHM unit (23), And an H and V separator 26 which separates horizontal and vertical synchronization signals from the image signal and outputs them to the scanning system 28. In this case, the scanning system 28 corresponds to a galvanometer and a polygon mirror in FIG. 1.

For convenience of explanation, the above-described R, G, B separation unit 21, A / D conversion unit 22, CHM unit 23, power unit 24, feedback unit 25, and H, V separation The part 26 is called a power supply part.

In the present invention configured as described above, the R, G, B separation unit 21 separates the input video signal into the respective colors of R, G, and B and outputs them to each A / D conversion unit 22. The A / D converter 22 converts analog R, G, and B signals into digital R, G, and B signals, respectively, and outputs them to the CHM unit 23. The CHM unit 23 adjusts the current strength of the digitized R, G, and B signals.

That is, the CHM unit 23 outputs from the power unit 24 to the LD 27 by adjusting the current intensity of the R, G, and B signals to enter the power unit 24 according to the gray level to be expressed. To modulate the energy. The R, G, and B LDs 27 supplied with the modulated output energy emit R, G, and B beams proportional to the power level of the power unit 24. As a result, the gray level is determined according to the intensity of the current controlled by the CHM unit 23. Here, the gray level of one pixel is determined by the intensity of the applied current during the unit time t (the time at which the beam per pixel is irradiated), as shown in FIG.

Therefore, when the screen is to be fully black, the R, G, and B currents are set to 0 so that the LD 27 is not supplied with power. In other words, the current supplied from the CHM unit 23 to the power unit 24 may be cut off. In addition, when the brightest light is required, the CHM unit 23 may increase the intensity of the R, G, and B currents to the maximum to maximize the power value supplied to the LD 27.

For example, to implement 256 gray scales, the current intensity is divided into 256 between 0 and maximum. The R, G, and B signals are output with the strength of the current corresponding to the gray level to be implemented. Then, the power unit 24 outputs a power proportional to the strength of the current to the R, G, B LD (27).

3 is a diagram showing an example of the ratio of the current applied to the power unit 24 and the output power ratio of the LD emitted from the power unit 24. The intensity of the input current is adjusted according to the gray level to provide a pulse shape. An example of supplying power to LD is shown.

In FIG. 3, if the current intensity is represented by the height of the vertical axis, the current intensity is adjusted according to the height. That is, it can be seen that the height of the vertical axis becomes the gray level, and power proportional to the intensity of each current is supplied to the LD 27.

Through this process, the R, G, and B beams emitted from the LD 27 are output to the feedback unit 25 and the scanning system 28.

The feedback unit 25 detects the power of the beam emitted from the LD 27 and feeds it back to the CHM unit 23 to maintain a constant power. That is, if any one or more LD outputs fall due to a lifetime problem among the R, G, and B LDs 27, the color temperature of the image actually intended is changed. In order to prevent this, the feedback unit 25 detects the output of the beam emitted from the LD 27 and generates a correction signal so that an output corresponding to the signal actually applied by the power unit 24 can be output. The output is (23). This allows the laser system to be used for a longer time than the LD self-life.

Meanwhile, the H and V separator 26 separates the horizontal and vertical synchronization signals from the input image signal and outputs the X and Y axes signals to the scanning system 28.

As described above, the power supply unit plays two roles. First, the power supply unit modulates the video signal using the CHM method. The second is to generate a drive waveform that controls the scanning system 28 to implement the position of the image signal on the screen. That is, the scanning system 28 scans the beams from the LD 27 on the X and Y axes in response to the horizontal and vertical synchronization signals from the H and V separators 26.

5 is a laser system to which the above-described LD optical module device is applied, and the power supply unit 51 has the same configuration as that of the power supply unit of FIG.

That is, the power supply unit 51 adjusts the intensity of the R, G, and B currents according to the image signal, that is, the gray level, and the power proportional to the intensity of the R, G, and B currents is each LD 52. Is supplied. The LD 52 emits R, G, and B beams in the form of pulses proportional to power and exits the mirrors 53 to 55. The mirrors 53 to 55 collect the input R, G, and B beams into one and output the galvanometer 56. That is, the B beam passes through the mirror 55 and enters the galvanometer 56 as it is, and the G beam is first reflected from the mirror 54 to the mirror 55, and then reflected from the mirror 55 again to the galvano. Incident with the meter 56. In addition, the R beam is reflected by the mirror 53, passes through the mirror 55, and then is reflected by the mirror 55 to enter the galvanometer 56. The beam thus collected is incident on the galvanometer 56 and then reflected again to enter the polygon mirror 57. The galvanometer 56 vibrates up and down at a speed synchronized with the vertical synchronizing signal V to implement a vertical image (Y-axis) of the screen, and the polygon mirror 57 is synchronized with the horizontal synchronizing signal H. While rotating at a high speed at a speed, the beam reflected from the galvanometer 56 is scanned to implement a horizontal image (X axis) of the screen. That is, the modulated light causes the scanning path to be changed in the vertical direction by the galvanometer 56, and the scanning path is changed in the horizontal direction by the polygon mirror 57 to form an image on the front of the screen.

In addition, when the white balance is to be adjusted, the present invention adjusts the intensity of the current in the CHM unit and outputs the power to the power unit, so that there is no loss of laser light.

As described above, according to the LD optical module apparatus of the laser system according to the present invention, by modulating the power supplied to the LD through the intensity adjustment of the current input to the power supply, the following effects are obtained.

First, the white balance is controlled by adjusting the amount of light of R, G, and B without losing light from LD, and the image can be expressed even at low laser power. In other words, when the user adjusts the display white balance, there is no waste of energy by adjusting the current of the power going directly into the LD.

Second, when the output of the LD gradually decreases due to the LD's own lifespan, the white balance can be kept constant by compensating the power of the LD as much as the output is separated by adjusting the current intensity by feedback. This also allows the use of laser displacer LDs longer than the LD self-life.

Third, the cost of the laser system can be lowered because no modulators such as AOM or EOM are used.

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.

Claims (3)

A signal processor for digitizing the R, G, and B signals from the input video signal; A current modulator adjusting the current intensity of each of the R, G, and B signals output from the signal processor according to a gray level; A power unit generating and outputting R, G, and B powers proportional to the R, G, and B currents output from the current modulator; A laser light source for emitting R, G, and B beams in proportion to the R, G, and B powers output from the power unit; And And a scanning unit configured to scan the R, G, and B beams emitted from the laser light source in a vertical direction and a horizontal direction to form an image on a screen. The LD optical module apparatus of claim 1, further comprising a feedback unit configured to detect an intensity of a beam output from the laser light source and feed it back to the current modulator as a current correction signal. The method of claim 1, wherein the current modulator The LD optical module device of the laser system, characterized in that to block the current supplied to the power unit when the screen on the black.