CN2727770Y

CN2727770Y - Laser color display device made by red, green, blue laser

Info

Publication number: CN2727770Y
Application number: CN 200420084249
Authority: CN
Inventors: 许祖彦; 侯玮; 李瑞宁; 林学春; 姚爱云; 王桂玲; 张瑛; 毕勇; 孙志培; 张鸿博; 崔大复; 徐贵昌
Original assignee: Institute of Physics of CAS
Current assignee: Institute of Physics of CAS
Priority date: 2004-07-26
Filing date: 2004-07-26
Publication date: 2005-09-21
Anticipated expiration: 2014-07-26

Abstract

The utility model relates to a laser color display device made by red, green, blue laser, comprising a red light laser, a green light laser and a blue light laser. The light paths of the output light paths are respectively and correspondingly placed with three decohering devices, a red light output light path is orderly provided with a first reflecting mirror, a liquid crystal light valve and a beam mixing prism after being decohered, the output light path of the light beam outputted by the green light laser apparatus is orderly provided with a second liquid crystal light valve and a beam mixing prism after being decohered, the output light path of the blue light laser is provided with a reflecting mirror, the middle light path of the reflecting mirror and the beam mixing prism is provided with a third liquid crystal light valve, and the light path of the light outputted finally by the beam mixing prism is provided with a projection mirror system. When the display device uses the lasers to proceed the laser display, the display device forms a large triangle area of the color degree and expands the color range of the existing laser display device; meanwhile, because the selected wave length approaches to three top angles of the triangle of the color degree, the display device displays vivid colors.

Description

Utilize the laser color display device of red, green, blue laser fabrication

Technical field

The utility model relates to a kind of laser display apparatus, particularly a kind of laser color display device that utilizes three kinds of laser fabrications of red, green, blue.

Background technology

At present, laser display has many families report, adopt different technology paths to obtain tricolor laser respectively, the three primary colours wavelength that is adopted also is not quite similar, as: calendar year 2001 SPIE magazine 4362 volume 203-212 pages or leaves, the tricolor laser device that the laser display of the Q-Peak company research and development of the report U.S. is used, after adopting the vibration one structure for amplifying generation high power 1047nm laser of LD pumping Nd:YLF, frequency multiplication obtains high-power 524nm green glow, pumping LBO OPO produces the flashlight of 898nm and the ideler frequency light of 1256nm then, flashlight and ideler frequency light difference frequency multiplication obtain the ruddiness of 449nm blue light and 628nm, remaining 524nm green glow is as the green-light source of three primary colours, this system also adopts the OPO structure, relatively simple for structure, the colorimetry triangle area that the three primary colours wavelength that obtains forms is approximately 2 times that fluorescent powder shows, yet, because the tricolor laser wavelength (628nm that this system adopts, 524nm, 449nm) especially the drift angle of the wavelength departure chromatic triangle of ruddiness is distant, and therefore the color that shows is bright-coloured inadequately.Because laser is line spectrum, has the color saturation higher than fluorescent powder, and can make that the color that shows is more bright-coloured by selecting three primary colours wavelength near the chromatic triangle drift angle.Also can make the chromatic triangle area of formation bigger simultaneously, demonstrate that nature is truer, more abundant colors, so laser display is one of significant development direction of high-end display technique, be subjected to international showing great attention to.

Summary of the invention

The purpose of this utility model is to overcome the defective of existing laser display apparatus; The purpose of this utility model is by selecting laser wavelength near the chromatic triangle drift angle, reach to make the laser display color more bright-coloured; Owing to increased the area of chromatic triangle, the laser display color is abundanter simultaneously; And use 3 eliminating coherence devices, make the laser display image utilize the laser color display device of red, green, blue laser fabrication more clearly.

The purpose of this utility model is achieved in that

A kind of laser color display device that utilizes the red, green, blue laser fabrication that the utility model provides is seen accompanying drawing 1, comprising: red laser 1, green (light) laser 5 and blue laser 8; Catoptron 3, first, second and the 3rd liquid crystal light valve 4,7,11, first, second and the 3rd eliminating

coherence device

2,6,9, beam cementing prism 12 and projection lens system 13; It is characterized in that: described red laser 1 output wavelength scope is 630～700nm; Described green (light) laser 5 output wavelength scopes are 510～520nm; Described blue laser 8 output wavelength scopes are 400～445nm; Wherein on the light path of red laser 1, green (light) laser 5, blue laser 8 tricolor laser device output light paths respectively correspondence first, second and the 3rd eliminating

coherence device

2,6,9 are set, order is settled first catoptron 3, first liquid crystal light valve 4, beam cementing prism 12 on 1 output light path of the red laser behind the eliminating coherence; Order is settled second liquid crystal light valve 7, beam cementing prism 12 on the output light path of light beam after expanding bundle of green (light) laser 5 outputs; Settle a catoptron 9 on blue laser 8 output light paths, settle the 3rd liquid crystal light valve 11 on the light paths in the middle of catoptron 9 and the beam cementing prism 12; On the light path of output light behind the beam cementing prism 12, settle projection lens system 13.

Described red laser 1 is by semiconductor laser LD, by LD pumping operation material for mixing Nd ^{+ 3}Ion, nonlinear crystal chamber inside/outside frequency multiplication mode obtain (shown in Fig. 3～4).

Described green (light) laser 5 is by semiconductor laser LD, or by LD pumping operation material for mixing Yb ^{+ 3}, nonlinear crystal chamber inside/outside frequency multiplication mode obtains (shown in Fig. 5～6).

Described blue laser 8 is: semiconductor laser (LD), operation material is for mixing Ti ^{+ 3}, Cr ^{+ 3}Outer frequency multiplication tunable laser in the chamber of ion or outside the chamber, or by LD pumping operation material for mixing Nd ^{+ 3}Ion, nonlinear crystal chamber inside/outside frequency tripling mode obtain (shown in Fig. 7～8).

Described red, green, blue tricolor laser device can be a continuous wave, also can be quasi-continuous or pulsating wave.

Described liquid crystal light valve comprises: light valves such as transmission-type liquid crystal light valve, reflective liquid crystal light valve or digital micro-mirror.

Described beam cementing prism is the X prism.

Described projection lens system comprises: pre-projecting type projection lens system or back projection type projection lens system etc.

Described eliminating coherence device comprises: catoptron transition that shakes, multimode optical fiber, position phase modulation panel, beam flying or light field reconstruction mode constitute.

Superiority of the present utility model: the utility model adopts red, green, blue tricolor laser device, and on the light path of laser instrument output light, place the eliminating coherence device respectively, its output ruddiness and blue light reflect light on the light valve in beam cementing prism the place ahead by catoptron, signal source is added to digital modulation signals on the liquid crystal light valve through conversion, unlatching and closure by control liquid crystal light valve unit, thereby the break-make of control light path, generation has the redness and the blue image of different gray-levels, green glow is directly incident on the green glow light valve in beam cementing prism the place ahead to be modulated, the tricolor laser that has different gray-levels after modulation incides in the projection lens system after synthetic a branch of by beam cementing prism, image three-colo(u)r just synthesizes a width of cloth coloured image like this, synthetic coloured image is projected on the suitable screen of distance again, can realize panchromatic demonstration, the panchromatic demonstration of laser that utilizes above-mentioned tricolor laser device to realize, the chromatic triangle area that forms is than the triangle area bigger (seeing accompanying drawing 2) of existing laser display system, the color that shows is horn of plenty more, simultaneously since the tricolor laser wavelength that uses more near the leg-of-mutton drift angle of colourity, therefore the color that shows is more bright-coloured.And use 3 eliminating coherence devices, make the laser display image more clear.And simple in structure, efficient height, life-span length, output are stablized, and its power can reach several watts to tens watts, can be widely used in fields such as laser home theater and laser large screen demonstration.

Description of drawings:

Fig. 1 is the laser color display device that utilizes the red, green, blue laser fabrication of the present utility model

Fig. 2 is that demonstration of the present utility model uses the chromatic triangle area of laser aid and other tricolor laser display device to compare synoptic diagram

Fig. 3 is that LD end pump Nd:YAG/Nd:YVO4 660/671nmnm red laser is formed synoptic diagram

Fig. 4 is that LD side pump Nd:YAG 660nm red laser is formed synoptic diagram

Fig. 5 is that LD end pump Yb:YAG 515nm green (light) laser is formed synoptic diagram

Fig. 6 is that LD pumping Yb:YAG thin slice 515nm green glow is formed synoptic diagram

Fig. 7 is that LD end pump Nd:YAG 1319nm and frequency 440nm blue laser are formed synoptic diagram

Fig. 8 is that LD side pump Nd:YAG 1319nm and frequency 440nm blue laser are formed synoptic diagram

Fig. 9 is a kind of eliminating coherence device structural representation

The drawing explanation:

1-660nm or 671nm red laser; 2-ruddiness eliminating coherence device;

3-red laser catoptron; 4-ruddiness liquid crystal light valve;

The 5-515nm green (light) laser; 6-green glow eliminating coherence device;

7-green glow liquid crystal light valve; The 8-440nm blue laser;

9-blue light eliminating coherence device; 10-blu-ray reflection mirror;

11-blue light liquid crystal light valve; 12-closes bundle (X) prism;

The 13-projection lens system; The 14-screen;

The 15-pump light source; The 16-coupled system;

17～19-resonator mirror; The 20-laser crystal;

The 21-nonlinear crystal; The 22-acousto-optic modulator;

23-90 ° of optical rotation plate; 24-assists mirror;

The 25-catoptron; The 26-LASER Light Source;

The 27-light beam; Catoptron on the 28-tilting mirror;

The 29-multiple surface rotating mirror; The axis of 30-multiple surface rotating mirror;

The 31-light beam moves the straight line of formation; The 32-display screen;

Embodiment

Embodiment 1

Light path according to Fig. 3 is made a 671/660nm red laser

Laser crystal 20 uses Nd:YVO4 or Nd:YAG crystal, plating blooming on it, and filming parameter is HT@808nm﹠amp; 1342nm or HT@808nm﹠amp; 1319nm, pump light source 15 adopts 808nm semiconductor laser LD, coupled system 16 is set on the place ahead light path of pump light source 15, by a pair of resonator mirror 17, the resonator cavity that makes with resonator mirror 18 resonant cavity mirrors 19, laser crystal 20 is placed in the middle of the resonator mirror 17, between the resonator mirror 18 resonant cavity mirrors 19 nonlinear optical crystal 21 is set; Put coupled system 16 and pump light source 15 on resonator mirror 17 output light paths.

Pump light is by after coupled system 16 pumpings, produce the fluorescence of 1342nm or 1319nm, by regulating

resonator mirror

17,18,19, make 1342nm or 1319nm fluorescence form vibration, produce laser, nonlinear optical crystal 21 is selected LBO or BiBO crystal for use, and the cutting angle of LBO is θ=0 °, =0 °, filming parameter is HT@1342nm﹠amp; 671nm or HT@1319nm﹠amp; 660nm is placed between

resonator mirror

18 and 19, and the ruddiness that the laser freuqency doubling of 1342nm or 1319nm wavelength is become 671nm or 660nm is by 18 outputs of chamber mirror; Regulate chamber mirror 19 and can obtain 671nm or the output of 660nm ruddiness.Can also in resonator cavity, insert modulator element, make the fundamental frequency light that produces high-peak power, to improve frequency-doubling conversion efficiency as acousto-optic Q-switching or locked mode device.

Coupled system 16 can adopt 1: 1 or 1.8: 1 imaging system product of companies such as relevant or OPC, also can oneself design customized according to the optical fiber output parameter of pump light source 15 is different.

Light path according to Fig. 5 is made a 515nm green (light) laser

Pump light source 15 is the 940nm semiconductor laser, coupled system 16 is set on the output light path of laser instrument, with a resonator cavity of forming by resonator mirror 17, resonator mirror 18 resonant cavity mirrors 19, laser crystal 20 is placed on the light path of resonator mirror 18 resonant cavity mirrors 19 centres, between the resonator mirror 18 resonant cavity mirrors 19 nonlinear optical crystal 21 is set.

Semiconductor laser is by behind the coupled system 16, pumping is gone up to laser crystal 20Yb:YAG and is produced 1030nm fluorescence, by regulating

resonator mirror

17,18,19, make 1030nm produce vibration, nonlinear crystal 21 is the 515nm green glow for LBO or ktp crystal are placed between

chamber mirror

18 and 19 the 1030nm frequency multiplication, regulating 19 makes the 515nm green glow from 18 outputs of chamber mirror, can also in resonator cavity, add birefringence filter plate equiwavelength tuned cell fundamental light wave length can be finely tuned within the specific limits, thereby the green wavelength of generation can be finely tuned between 510nm～520nm.Can also in resonator cavity, insert modulator element, make the fundamental frequency light that produces high-peak power, to improve frequency-doubling conversion efficiency as acousto-optic Q-switching or locked mode device.

Make the blue laser of a 440nm according to the light path of Fig. 7, just be also to be included among Fig. 7 on the light path in the middle of resonator mirror 19 and the nonlinear optical crystal 21, also place another piece nonlinear optical crystal 26 with the difference of Fig. 5.

Semiconductor laser is by coupled system 16 pumping laser crystal 2 0Nd:YA6 crystal, produce 1319nm fluorescence, by regulating

resonator mirror

17,18,19, make 1319nm produce vibration,

nonlinear crystal

21 and 26 be respectively frequency-doubling crystal LBO and and crystal LBO frequently, be placed on successively between

chamber mirror

18 and 19, the laser of 1319nm is become 440nm, regulate chamber mirror 19 and make the 440nm blue light by 18 outputs of chamber mirror.Can also in resonator cavity, insert modulator element, make the fundamental frequency light that produces high-peak power, to improve frequency-doubling conversion efficiency as acousto-optic Q-switching or locked mode device.

With reference to figure 1, utilize three kinds of above-mentioned laser instruments, make a laser display apparatus

Use above-mentioned three laser instruments making, as the red laser among the utility model Fig. 11, green (light) laser 5 and blue laser 8, the corresponding respectively eliminating coherence device 2 that a red, green, blue laser is set in each laser instrument platform back, 6,9, order is settled first catoptron 3, common transmission-type liquid crystal light valve 4, beam cementing prism 12 on red laser 1 output light path after expanding bundle; The light beam of green (light) laser 5 outputs order on the output light path behind the eliminating coherence is settled the second transmission-type liquid crystal light valve 7, beam cementing prism 12; Settle a catoptron 9 on blue laser 8 output light paths, settle the 3rd transmission-type liquid crystal light valve 11 on the light paths in the middle of catoptron 9 and the beam cementing prism 12; On the light path of output light behind the beam cementing prism 12, settle projection lens system.This eliminating coherence device can adopt common oscillating mirror, beam flying or light field reconstruction mode to constitute.Display screen 32 among Fig. 9 is replaced the uniform light field that forms can being reflexed on preceding red, the blue light light valve 4,11 of X beam cementing prism 12 by the catoptron 3 of ruddiness among Fig. 1 and blue light and 10 to be modulated.The green glow light field that forms is directly modulated by the green glow light valve 7 before the X beam cementing prism 12, red, green, blue light beam after the modulation is synthetic a branch of after conventional pre-projecting type projection lens system 13 projects on the suitable screen 14 of distance through X beam cementing prism 12, can realize that bright in luster, abundant image shows.The beam cementing prism that present embodiment uses is the X prism of buying on the market, it is glued together behind grinding, polishing, plated film respectively by four prisms and forms (as shown in FIG.), glue and face filming parameter are: Rs＞95%@420-475nm, Rs＞95%@600-680nm, Tp＞95%@490-580nm (45 ° of incident), four right angle face filming parameters are: R＜0.25%@420-680nm.

Embodiment 2

Light path according to Fig. 4 is made a side pump 660nm red laser

Laser crystal 20 adopts the Nd:YAG rod, two logical light face plating 1319nm anti-reflection films; Pump light 15 adopt multidimensional 808nm semiconductor laser arrays according to certain shape and position be placed on laser crystal 20 around, the parts of Zu Chenging are called a laser head like this, can only use a laser head in the light path, also can a plurality of laser head serial connections use, when using two laser head serial connections, between insert 90 degree optical rotation plates 23 with the compensation thermally induced birefringence, on the light path on laser head both sides, set gradually by a pair of resonator mirror 17, the composite resonant cavity that resonator mirror 18 resonant cavity mirrors 19 are formed, a nonlinear optical crystal 21 is placed between the resonator mirror 18 resonant cavity mirrors 19; Two laser heads and between 90 degree optical rotation plates 23 all be placed between

resonator mirror

17 and 18.

During pump light 15 pumping laser crystal 2s 0, can produce the fluorescence of 1319nm,, make 1319nm fluorescence form vibration by regulating

resonator mirror

17,18, produce laser, can also insert modulator element 22 acousto-optic modulators in the light path and make generation high-peak power laser, nonlinear optical crystal 21 is selected lbo crystal for use, can be placed between the 18 and 19 chamber mirrors, also can not use chamber mirror 18, the cutting angle of LBO is θ=0 °, =0 °, and filming parameter is HT@1319nm﹠amp; 660nm produces the ruddiness of 660nm with the laser freuqency doubling of 1319nm wavelength,

regulates chamber mirror

18,19 and can obtain the output of 660nm ruddiness, and resonator cavity also can adopt the folded cavity structure to improve shg efficiency.Modulator element 22 can also be electro-optical Q-switch or locked mode device, can produce the fundamental frequency light of high-peak power equally, to improve frequency-doubling conversion efficiency.

Light path according to Fig. 6 is made a 515nm thin slice green (light) laser

Pump light 15 is the semiconductor laser of 940nm, laser crystal 2Yb:YAG thin slice placed side by side and auxiliary mirror 24 below it, the Yb:YAG sheet thickness is about 0.2mm, the high-reflecting film of its rear surface plating 1030nm high-reflecting film and pump light 940nm, the anti-reflection film of front surface plating 1030nm and 940nm, auxiliary mirror 24 auxiliary mirrors 24 are flat mirror, plating 940nm high-reflecting film, pump light and auxiliary mirror position symmetry are placed, in the middle of laser crystal is placed on, the catoptron 25 of four position symmetries is placed in its back, its filming parameter is the 940nm high-reflecting film, reserve between four catoptrons about a 3mm the hole so that oscillation light freely pass through, place successively on the dead astern light path of laser

crystal resonator mirror

18 and 19 and the rear end face of laser crystal form resonator cavity, a nonlinear crystal 21 is set between the

resonator mirror

18 and 19.

Pump light 15 incides first catoptron 25, pump light is reflected on the laser crystal 20Yb:YAG thin slice through catoptron, absorption portion 940nm pump light, second catoptron 25 of residual pump light reflected back, after be reflected on the auxiliary mirror 24, auxiliary mirror 24 is flat mirror, plating 940nm high-reflecting film, pump light is mapped on the 3rd catoptron through auxiliary mirror reversal, after be reflected back toward on the laser crystal thin slice, behind the absorbent portion wheel cylinder light, residual pump light reflexes on the 4th catoptron, after be reflected back toward on the laser crystal thin slice, so pump light comes and goes on the thin slice crystal and repeatedly passes through to increase the absorption to pump light, the 1030nm high-reflecting film of laser crystal Yb:YAG rear surface and

chamber mirror

18,19 form resonator cavity produces 1030nm laser generation, nonlinear crystal 21 is the 515nm green glow for LBO or ktp crystal are placed between

chamber mirror

18 and 19 the 1030nm frequency multiplication, regulating 19 makes the 515nm green glow from 18 outputs of chamber mirror, can also in resonator cavity, add birefringence filter plate equiwavelength tuned cell fundamental light wave length can be finely tuned within the specific limits, thereby the green wavelength of generation can be finely tuned between 510nm～520nm.Can also in resonator cavity, add modulator element, make the fundamental frequency light that produces high-peak power, to improve frequency-doubling conversion efficiency as acousto-optic Q-switching or locked mode device.

Make the blue laser of a 440nm according to the light path of Fig. 8, just be also to be included among Fig. 7 on the light path in the middle of resonator mirror 19 and the nonlinear optical crystal 21, also place another piece nonlinear optical crystal 26 with the difference of Fig. 4.

Pump light 15 pumping laser crystal 2s 0 produce 1319nm fluorescence, by regulating

resonator mirror

17,18,19, make 1319nm fluorescence form vibration, produce laser, can also insert modulator element (22) acousto-optic modulator in the light path and make generation high-peak power laser,

nonlinear crystal

21 and 26 be respectively frequency-doubling crystal LBO and and crystal LBO frequently, two logical light faces are coated with 1319nmHT, 660nmHT and 440nmHT film, frequency-doubling crystal LBO adopts I class coupling and the II of crystal LBO employing frequently class coupling to obtain high conversion efficiency, is placed on successively between

chamber mirror

18 and 19, the laser of 1319nm is become 440nm, regulate chamber mirror 19 and make the 440nm blue light of generation by 18 outputs of chamber mirror.Modulator element 22 can also be electro-optical Q-switch or locked mode device, can produce the fundamental frequency light of high-peak power equally, to improve frequency-doubling conversion efficiency.

With above-mentioned three laser instruments as the red laser among Fig. 11, green (light) laser 5 and blue laser 8, the back is placed red respectively, green, blue laser eliminating coherence device 2,6,9, red, green, the eliminating coherence device of blue laser can adopt the method among the embodiment one, also can adopt the multimode optical fiber method, methods such as mirrors vibrate method, the multimode optical fiber method promptly be with three look laser respectively the scioptics group with laser coupled in three root multimode fibers, light field is rebuilt to reduce the coherence in optical fiber, expand the more uniform light field that bundle forms certain area by the beam-expanding system of forming by lens respectively after the output, realize expanding bundle thus, the purpose of shimming and eliminating coherence.Ruddiness and blue light by catoptron 3 and 10 with red, the blue light light valve 4 of beam reflection before the X beam cementing prism 12, modulate on 11, green glow is directly modulated by the green glow light valve 7 before the X beam cementing prism 12, red, green, blue light beam after the modulation is synthetic a branch of after projection lens system 13 projects on the suitable screen 14 of distance through X beam cementing prism 12, can realize that bright in luster, abundant image shows.Described eliminating coherence device also can adopt patent " a kind of scanning type area light that is used for the laser video demonstration " (patent No. is ZL02251313.2) described method, the light path synoptic diagram as shown in Figure 9, red, green, blue laser replaces the LASER Light Source 26 among Fig. 9 respectively, after the reflection of each different catoptron 28 of the angle on the multiple surface rotating mirror 29, form the more uniform light field of certain area, so just reached the purpose that expands bundle and shimming, because light beam is in quick scanning, the light beam that same position occurs is different light constantly, has therefore also reached the purpose of eliminating coherent interference.

The utility model is according to the colorimetry theory, further expand colour gamut, obtain the blue laser that green (light) laser about 515nm and LD pumping Nd:YAG 1319nm spectral line and mode frequently obtain 440nm by the mode that adopts LD pumping Nd:YVO4/Nd:YAG frequency multiplication mode to obtain red laser, the LD pumping Yb:YAG frequency multiplication of 671nm or 660nm, thereby expanded the colour gamut of three primary colours of the laser display of existing report greatly, the chromatic triangle area that forms is 2.2 times of fluorescent powder approximately, can show more bright-coloured, more horn of plenty and real color.

Claims

1. a laser color display device that utilizes the red, green, blue laser fabrication comprises: red laser (1), green (light) laser (5) and blue laser (8); Catoptron (3), first, second and the 3rd liquid crystal light valve (4,7,11), first, second and the 3rd eliminating coherence device (2,6,9), beam cementing prism (12) and projection lens system (13); It is characterized in that: described red laser (1) output wavelength scope is 630～700nm; Described green (light) laser (5) output wavelength scope is 510～520nm; Described blue laser (8) output wavelength scope is 400～445nm; Wherein on the light path of red laser (1), green (light) laser (5), blue laser (8) tricolor laser device output light path respectively correspondence first, second and the 3rd eliminating coherence device (2,6,9) are set, order is settled first catoptron (3), first liquid crystal light valve (4), beam cementing prism (12) on red laser (1) output light path after expanding the eliminating coherence bundle; Order is settled second liquid crystal light valve (7), beam cementing prism (12) on the output light path of light beam after expanding bundle of green (light) laser (5) output; Settle a catoptron (9) on blue laser (8) output light path, settle the 3rd liquid crystal light valve (11) in the middle of catoptron (9) and the beam cementing prism (12) on the light path; On the light path of output light behind the beam cementing prism (12), settle projection lens system (13).

2. by the described laser color display device that utilizes the red, green, blue laser fabrication of claim 1, it is characterized in that: the red laser (1) that described output wavelength scope is 630～700nm comprising: the solid-state laser of semiconductor laser, diode-end-pumped, diode-end-pumped operation material are for mixing Nd ^{+ 3}Ion solid-state laser, nonlinear crystal chamber inside/outside frequency multiplication mode obtain laser instrument, or optical parametric oscillator.

3. by the described laser color display device that utilizes the red, green, blue laser fabrication of claim 1, it is characterized in that: the green (light) laser (5) that described output wavelength scope is 510～520nm comprising: the solid-state laser of semiconductor laser, diode-end-pumped or by the diode-end-pumped operation material for mixing Yb ^{+ 3}The solid-state laser that solid-state laser, nonlinear crystal chamber inside/outside frequency multiplication mode obtain, or optical parametric oscillator.

4. by the described laser color display device that utilizes the red, green, blue laser fabrication of claim 1, it is characterized in that: the blue laser (8) that described output wavelength scope is 400～445nm comprising: the solid-state laser of semiconductor laser, diode-end-pumped, operation material are for mixing Ti ^{+ 3}, Cr ^{+ 3}In the chamber of ion or outside the chamber outer frequency multiplication tunable laser or by the diode-end-pumped operation material for mixing Nd ^{+ 3}The laser instrument that ion, nonlinear crystal chamber inside/outside frequency tripling mode obtain, or optical parametric oscillator.

5. by the described laser color display device that utilizes the red, green, blue laser fabrication of claim 1, it is characterized in that: described red laser (1), green (light) laser (5) and blue laser (8) comprising: the running or the laser instrument of quasi continuous operation continuously.

6. by the described laser color display device that utilizes the red, green, blue laser fabrication of claim 1, it is characterized in that: described liquid crystal light valve comprises: transmission-type liquid crystal light valve or reflective liquid crystal light valve.

7. by the described laser color display device that utilizes the red, green, blue laser fabrication of claim 1, it is characterized in that: described eliminating coherence device comprises: catoptron transition, multimode optical fiber, optical beam scanner shake.