KR100303831B1 - Optical pumping laser valve and optical pumping laser - Google Patents

Abstract

The light pump laser valve according to the present invention comprises a vertical resonant surface discharge laser diode, an optical pumping source and a light valve. Vertical resonance surface discharge laser diodes generate resonance for light of a certain wavelength. The optical pumping source pumps the vertical resonant surface discharge laser diode to produce a laser beam. The light valve filters the laser beam emitted from the vertical resonance surface discharge laser diode to form an image screen.

Description

Optical pumping laser valve and optical pumping laser

The present invention relates to an optical pump laser valve and an optical pump laser device.

1 is a schematic configuration diagram of a stereoscopic image projector using a conventional liquid crystal light valve (LCLV). As shown in the drawing, the conventional stereoscopic image projector produces white light emitted from the high-pressure metal-halide lamp 100, which is a light source, collimates the collimating lens 200 to focus on the liquid crystal display panel 300, and the liquid crystal display. The panel 300 filters and transmits the incident light in accordance with the image signal. The transmitted light is focused on the optical lens system 400 to project on the screen 500 to obtain an image screen. However, the stereoscopic image projector using the conventional liquid crystal light valve uses high-pressure metal-halide light, but the light projected by the liquid crystal display panel has a high dispersion angle and low luminance, resulting in a low contrast level. Crazy, not clear

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and provides an optical pump laser valve and an optical pump laser device capable of realizing an image of a laser and making the device compact while improving the brightness and contrast of the projection display device. The purpose is.

1 is a schematic configuration diagram of a stereoscopic image projector using a conventional liquid crystal light valve,

2 is a cross-sectional view showing a schematic structure of an integrated light pump laser valve according to the present invention;

3 is a cross-sectional view showing a schematic structure of a separate light pump laser valve according to the present invention;

4 is a cross-sectional view illustrating an example in which a laser resonator of the light pump laser valve of FIG. 2 or 3 is formed of a single crystal;

5 is a cross-sectional view illustrating an example in which a laser resonator of the light pump laser valve of FIG. 2 or 3 is formed of a quantum well multilayer.

<Description of the symbols for the main parts of the drawings>

1. metal reflector 2. inert gas

3. Transparent conductive film 4. Oxide mirror

5. Active Layer 6. Dispersion Bragg Reflector

7. Transparent board 8. Light valve (liquid crystal display panel)

9, 19. Vertical resonant surface discharge laser diode

10. Optical pumping source 11. Metal reflector

12. Inert gas 13. Transparent conductive film

14. Oxide Mirror 15. Active Layer

16. Dispersion Bragg Reflector 17. Transparent Substrate

18. Light Valve (Liquid Crystal Display Panel) 20. Light Pumping Source

100. White light source 200. Collimating lens

300. Liquid crystal display panel 400. Projection lens

500. Screen

The optical pump laser valve of the present invention for achieving the above object is provided with a vertical resonance surface discharge laser diode, an optical pumping source and an optical valve. The vertical resonance surface discharge laser diode causes resonance with respect to light having a constant wavelength. The optical pumping source pumps the vertical resonant surface discharge laser diode to generate a laser beam. The light valve filters the laser beam emitted from the vertical resonance surface discharge laser diode to form an image screen.

Preferably, in the vertical resonance surface discharge laser diode, the active layer is formed of a single crystal layer of a group II-VI or group III-V compound semiconductor, or a heterogeneous material of a group II-VI or group III-V compound semiconductor is alternately bonded. It is formed of a multi-quantum well layer or a superlattice layer, and the mirror forming the resonator in the vertical resonance surface discharge laser diode is made of a dichroic mirror formed by alternately bonding an oxide dielectric having a relatively high refractive index and a low refractive index, respectively. Or a distributed Bragg reflector formed by alternately bonding group II-VI or group III-V compound semiconductors having relatively high and low refractive indices, respectively. On the other hand, the light pumping source is preferably made of a gas discharge tube in the form of a point light source or a surface light source, the light valve is preferably made of a liquid crystal display panel. In addition, in the present invention, the laser resonator and the optical pumping source are preferably formed in one piece directly bonded or separately formed separate type.

In addition, the optical pump laser device of the present invention for achieving the above another object comprises a vertical resonance surface discharge laser diode and an optical pumping source. The vertical resonance surface discharge laser diode causes resonance with respect to light having a constant wavelength. The optical pumping source pumps the vertical resonant surface discharge laser diode to generate a laser beam.

Hereinafter, an optical pump laser valve and an optical pump laser apparatus according to the present invention will be described in detail with reference to the drawings.

2 is a cross-sectional view showing a schematic structure of an integrated light pump laser valve according to the present invention. As shown, the integrated optical pump laser valve according to the present invention is largely pumped by the laser oscillation unit, that is, the vertical resonance surface discharge laser diode 9 as a laser cavity, and the vertical resonance surface discharge laser diode 9 The main light source includes a light source 8, a light pumping source 10, and a light valve 8 for filtering the laser beam emitted from the vertical resonance surface discharge laser diode 9 into an image screen. Here, the vertical resonant surface discharge laser diode 9 and the light pumping source 10 may be directly integrated. The detailed configuration of each part may include a light reflector 1 using a glow discharge principle. ), An inert gas (2), a transparent conductive film (3), and the vertical resonant surface discharge laser diode (9) comprises an oxide mirror (4), an active layer (5), a distributed Bragg reflector (6), and a transparent substrate (7). And the light valve 8 is formed of a liquid crystal display panel.

3 is a cross-sectional view showing a schematic structure of a separate light pump laser valve according to the present invention. As shown, the separate type optical pump laser valve according to the present invention has a large laser oscillation unit, that is, a vertical resonant surface discharge laser diode 19 as a laser resonator, and a light source that pumps the vertical resonant surface discharge laser diode 19, that is, light. It consists of a light valve 18 for filtering the laser beam emitted from the pumping source 20 and the vertical resonance surface discharge laser diode 19 to the image screen. Here, the vertical resonant surface discharge laser diode 9 and the light pumping source 20 are configured separately and separately. The detailed configuration of each illustrated part is that the light pumping source 20 using the glow discharge principle includes a metal reflector 11, an inert gas 12, a transparent conductive film 13, and a vertical resonant surface discharge laser diode 9 ) Comprises an oxide mirror 14, an active layer 15, a distributed Bragg reflector 16 and a transparent substrate 17, and the light valve 18 is a liquid crystal display panel.

The vertical resonant surface discharge laser diodes 9 and 19 in the two embodiments of the above-described integrated and discrete types are Fabry-Perot type vertical cavity surface emitting lasers (VCSELs), as shown in FIGS. 4 and 5. It is produced in the form of. That is, the vertical resonator surface emitting laser has a first reflecting layer (4, 14) that transmits ultraviolet light and reflects visible light, an active layer (5, 15) which is a light emitting source composed of a semiconductor, and a part having a partial reflectance and a laser which is oscillated. It consists of the two reflection layers 6 and 16 and the transparent substrates 7 and 17 which are support plates. The area of the vertical resonance surface discharge laser diodes 9 and 19 is not limited in size regardless of the area of the light valves 8 and 18.

Here, the active layers of the vertical resonance surface discharge laser diodes 9 and 19 may be formed of the single crystal layers 5 and 15 of the group II-VI or group III-V compound semiconductor, as shown in FIG. 4. The material used here uses a material having an energy bandgap suitable for emitting light in the visible region. The material used is a compound using Cd, Zn, Mg, S, Se and a compound using Ga, Al, In, N. These compounds are adjusted to take the form of binary, ternary, or quaternary with a certain component ratio so as to have an energy band gap suitable for each of red, green, and blue emission of visible light. In addition, the active layers of the vertical resonant surface discharge laser diodes 9 and 19 have a multi-quantum well or superlattice structure through alternating junctions of dissimilar materials of a group II-VI or group III-V compound semiconductor, as shown in FIG. 5. It may be formed as (5, 15). The material used here also uses a material having an energy band gap suitable for emitting light in the visible region. The material used is a compound using Cd, Zn, Mg, S, Se and a compound using Ga, Al, In, N. These compounds are also adjusted to take the form of binary, ternary, or quaternary with a certain component ratio so as to have an energy band gap suitable for each of red, green, and blue emission of visible light. As such, forming the active layers 5 and 15 into a multi-quantum well or a superlattice structure makes it easy to design an energy band gap so that an emission transition level suitable for light emission of red, green, and blue is formed, and wells and barrier materials. This is because it is easy to manufacture through the adjustment of the component ratio, thickness and number of layers.

Further, in the above-mentioned two types of integrated and discrete embodiments, the resonator mirrors 4, 14, 6, and 16 constituting the vertical resonant surface discharge laser diodes 9 and 19 are formed by alternating bonding of oxide dielectrics having high refractive index and low refractive index. It consists of a dichroic mirror. In this case, the first reflection layers 4 and 14 are formed in a multilayer structure that transmits ultraviolet rays and reflects visible light. The ultraviolet light excites the semiconductor active layers 5 and 15 and the visible light generated in the active layers 5 and 15 And to reflect resonance amplification within the resonator. The second reflection layers 6 and 16 are partially reflective layers, and the reflectance is adjusted to be lower than that of the first reflection layers 4 and 14 so that the amplified light is projected out of the resonator together with resonance amplification of the light generated in the active layer. It is manufactured to have a reflecting band corresponding to the blue wavelength. In another embodiment, the resonator mirrors 4, 14, 6, 16 may be made of distributed Bragg reflectors in alternating junctions of high and low refractive index II-VI or III-V compound semiconductors. Thus, the two resonator mirrors are composed of alternating bonding of high and low refractive index materials, and the distributed Bragg reflector is a mirror composed of multilayer thin films using interference effects at the interface. The material used herein is a compound using the same Cd, Zn, Mg, S, Se, and Ga, Al, In, N as the active layer material, these compounds in the form of binary, ternary, or quaternary of a certain ratio Used. The thickness, component ratio, and number of layers are adjusted to have reflecting bands and reflectances suitable for laser emission of red, green, and blue of visible light.

Further, in the above two embodiments, the light source for pumping the vertical resonant surface discharge laser diodes 9 and 19, that is, the light pumping source 10 and 20 is configured as an inert gas discharge tube which effectively emits light in the ultraviolet region. It is configured in the form of a light source or a surface light source.

In the above two embodiments, the light valves 8 and 18 for receiving the image signal and filtering the laser beams emitted from the vertical resonance surface discharge laser diodes 9 and 19 into the image screen are mainly made of a liquid crystal display panel. Do.

On the other hand, the optical pump laser device according to the present invention is the same as the structure in which the light valves 8 and 18, that is, the liquid crystal display panel, are removed from the optical pump laser valve structure having the configuration as described above. When the light valve is removed in this way, it can be applied as a laser device. Therefore, since the structure and operation are the same as the structure and operation of the optical pump laser valve, description thereof is omitted.

As described above, the optical pump laser valve (and the optical pump laser device) according to the present invention includes a vertical resonance surface discharge laser diode which causes resonance for light of a constant wavelength; An optical pumping source for pumping the vertical resonant surface discharge laser diode to generate a laser beam; And a light valve for filtering the laser beam emitted from the vertical resonance surface discharge laser diode to form an image screen, each having the following advantages.

1. Using a surface emitting laser with a small dispersion angle and linearity, it is possible to construct a projection display device with low loss, thereby improving the brightness of the screen.

2. By applying the laser directly, the clarity is improved than the conventional projection display device.

3. The vertical resonant surface discharge laser diode has high luminous efficiency and low light loss, which enables lower power consumption.

4. It is possible to compact because it uses simple and small volume material and parts.

5. It is possible to realize new image culture by laser.

6. It is possible to realize the laser device by the new pumping method.

The present invention is not limited to the above embodiments, but may be modified and improved by those skilled in the art within the spirit and scope of the invention as defined in the claims.

Claims (11)

A vertical resonance surface discharge laser diode which causes resonance with respect to a constant wavelength of light; An optical pumping source for pumping the vertical resonant surface discharge laser diode to generate a laser beam; And A light valve for filtering the laser beam emitted from the vertical resonance surface discharge laser diode to form an image screen; An optical pump laser valve comprising: The method of claim 1, And the active layer of the vertical resonant surface discharge laser diode is formed of a single crystal layer of a group II-VI or group III-V compound semiconductor. The method of claim 1, In the vertical resonance surface discharge laser diode, the active layer is an optical pump laser valve, characterized in that the heterogeneous material of the group II-VI or III-V compound semiconductor is formed as a multi-quantum well layer or a superlattice layer through alternating bonding. The method of claim 1, And a mirror forming a resonator in the vertical resonant surface discharge laser diode comprises a dichroic mirror formed by alternately bonding an oxide dielectric having a relatively high refractive index and a low refractive index. The method of claim 1, The mirror of the resonator in the vertical resonance surface discharge laser diode is an optical pump comprising a distributed Bragg reflector formed by alternating bonding of II-VI or III-V compound semiconductors having relatively high and low refractive indices, respectively. Laser valve. The method of claim 1, The optical pumping source is an optical pump laser valve, characterized in that consisting of a gas discharge tube. The method of claim 1, The optical pumping source is a light pump laser valve, characterized in that consisting of a point light source or a surface light source. The method of claim 1, The light valve is a light pump laser valve, characterized in that consisting of a liquid crystal display panel. The method of claim 1, And the vertical resonant surface discharge laser diode and the optical pumping source are integrally bonded to the optical pump. The method of claim 1, And the vertical resonant surface discharge laser diode and the optical pumping source are separately formed in a separate type. A vertical resonance surface discharge laser diode which causes resonance with respect to a constant wavelength of light; And An optical pumping source for pumping the laser resonator to generate a laser beam; Optical pump laser device characterized in that provided.