CN207067640U - Excitation light source system and projector equipment - Google Patents

Abstract

A kind of projector equipment the utility model discloses excitation light source system and using the excitation light source system, need not be using devices such as the colour wheel of existing product and square rods, by setting relay system, microlens array, spatial light modulator and scattering powder array, so that each exciting light is incident to scattering powder array through spatial light modulator modulation and imaging is emitted after microlens array is collected after the scattering powder array scattering, color and the higher illumination of brightness uniformity are realized, there is good Consumer's Experience.

Description

Excitation light source system and projector equipment

Technical field

Optical technical field is the utility model is related to, more particularly to a kind of field of projection display.

Background technology

At present, the various aspects among projection display applications to life, its core is spatial light modulator.It is common Spatial light modulator has MEMS technology DMD DMD, HTPS LCD display chips and reflection type LCD device LCOS.Root It is different according to the number of optical projection system spatial light modulator, it is generally divided into one chip and three-panel projection system.Single-panel projection System is simple in construction with its, and cost is relatively low, occupies the major part of middle and low-end market.Current most spatial light modulator is all It is passive type, it is necessary to a color and the higher illumination of brightness uniformity.Therefore complex optics must be designed The combination of system and excitation source obtains uniformly and the enough excitation light source system of brightness.By taking one chip DMD systems as an example, Excitation source needs sequentially to provide RGB illumination light.Therefore the monochromatic light or logical for needing sequential to open in excitation light source system Cross the transmission wave band that optical filter realizes timing variations., must also provider in excitation light source system in order to provide uniform illumination The dodging devices such as rod carry out Homogenization Treatments to light.

It is existing one chip DMD optical projection systems as shown in Figure 1, semiconductor laser excitation source 101 is saturating by collecting Mirror 102 is focused on the colour wheel 103 of rotation, and colour wheel 103 is the fluorescent powder color wheel as shown in Fig. 2, and sequential is formed after colour wheel On red, green, blue three primary colours light, incided after 104 even light of square rod, then by light relay system on TIR prism 105, instead It is mapped on dmd chip 106 and is modulated, by the final output image of projection lens 107.LASER Excited Fluorescence powder obtains three bases Color fluorescence, is limited to the energy density of exciting light, and the hot saturation of fluorescent material can cause excitation source brightness to be limited.

For these reasons so that excitation light source system structure complexity of the prior art is high, shared volume is big, limitation The back work distance of camera lens is from have impact on the performance of product.Therefore it is real to be necessary to provide a kind of new excitation light source system to solve Certainly above mentioned problem.

Utility model content

The utility model is mainly solving the technical problems that provide a kind of excitation light source system and projecting method, using simple System can realize color and the higher illumination of brightness uniformity, there is good Consumer's Experience.

In order to solve the above technical problems, the technical scheme that the utility model uses is：A kind of excitation source system is provided System, the excitation light source system include：Multiple excitation sources, relay system, microlens array, spatial light modulator and display system System, wherein,

The excitation source includes at least one green (light) laser for sending green exciting light, at least one red that sends swashs Luminous red laser and at least one blue laser for sending blue excitation light；

The relay system is located in the light path of the exciting light, each exciting light sent for collecting excitation source；

The microlens array includes playing before the spatial light modulator convergence and respectively excites the first micro- of light action Lens array and the second microlens array, first microlens array and second microlens array include multiple lenticule lists Member；

The spatial light modulator is used to modulate each exciting light, and each exciting light is through described in the first microlens array incidence Spatial light modulator；

The display system is scattering powder array, for being scattered to each exciting light；

The exciting light is incident to the scattering powder array through spatial light modulator modulation and dissipated from the scattering powder array After penetrating imaging is emitted after second microlens array collection.

Preferably, the spatial light modulator includes being used for the multiple pixel cells for modulating different exciting lights, the scattering Powder array includes multiple scattering powder units, and the scattering powder unit corresponds with the pixel cell.

Preferably, the excitation light source system includes being used to converge exciting light between the excitation source and relay system Collection system.

Preferably, after the collection system is focused to each exciting light, focus that each exciting light is formed in collection system One first focal plane is formed, each exciting light forms EDS maps on first focal plane.

Preferably, the microlens array also includes the second lenticule battle array after display system in each exciting light light path Row, it is excitation source that the excitation light source system includes setting gradually along optical axis direction, collection system, relay system, first micro- Lens array, spatial light modulator, scattering powder array and the second microlens array.

Preferably, the collection system includes and excitation source multiple collecting lenses correspondingly.

Preferably, the green (light) laser, red laser and blue laser along optical axis direction in the display system On projection on the same line.

Preferably, a pixel cell of the spatial light modulator is correspondingly formed one by a scattering powder unit Individual pixel, the pixel comprise at least a red, green and sub- pixel of blue three.

Preferably, the green (light) laser, the red laser and the blue laser along optical axis direction described Projection in display system is arranged in a matrix fashion, and the quantity of green (light) laser is the quantity of red laser and blue laser Sum, any two green (light) laser are non-conterminous.

Preferably, a pixel cell of the spatial light modulator is correspondingly formed one through a scattering powder unit Pixel, the pixel comprise at least red, two green, sub- pixels of blue four.

Preferably, the collection system includes a collecting lens and is used to adjust exciting light in exciting light light path Light path to the collecting lens at least two sequential open light splitting eyeglass.

Preferably, the light splitting eyeglass includes the anti-blue light that is arranged in blue laser light path and yellow eyeglass and is arranged on thoroughly Counter in red laser light path is popular in blue or green eyeglass, the reflection or lens light of the exciting lights of different excitation sources by light splitting eyeglass Road is overlapped, and the first focal plane of collecting lens is converged at through collecting lens.

Preferably, a pixel cell of the spatial light modulator is correspondingly formed a pixel through a scattering powder unit Point.

Preferably, the microlens array also includes the second lenticule battle array after display system in each exciting light light path Row, the excitation light source system include the excitation source, the first microlens array, space light modulation set gradually along optical axis direction Device, relay system, scattering powder array and the second microlens array.

Preferably, the same plane that different excitation sources are converged on optical axis with the incidence angle different from optical axis is described flat Face is identical with the distance of optical axes crosspoint to each excitation source, and different exciting lights form angle distribution on the plane, and through first Microlens array is converted into each pixel cell that EDS maps incide spatial light modulator.

Preferably, a pixel cell of the spatial light modulator is correspondingly formed a picture by a scattering powder unit Vegetarian refreshments, the pixel comprise at least a red, green and sub- pixel of blue three.

Preferably, the spatial light modulator is any one in LCD, DMD or LCOS.

Spatial light modulator is in order to solve the above technical problems, another technical scheme that the utility model uses is：There is provided A kind of projector equipment, the projector equipment include any one of previously described excitation light source system.

The beneficial effects of the utility model are：The situation of prior art is different from, the utility model provides a kind of exciting light Source system and the projector equipment using the excitation light source system, without devices such as the colour wheel using existing product and square rods, lead to Cross setting relay system, microlens array, spatial light modulator and scattering powder array so that each exciting light is through spatial light modulator Modulation is incident to scattering powder array and imaging is emitted after microlens array is collected after the scattering powder array scattering, realizes Color and the higher illumination of brightness uniformity, have good Consumer's Experience.

Brief description of the drawings

Fig. 1 is the structural representation of optical projection system in existing product；

Fig. 2 is the structural representation of the colour wheel of optical projection system in existing product；

Fig. 3 is the structural representation of the first embodiment of the utility model excitation light source system；

Fig. 4 is that the first embodiment of the utility model excitation light source system is irradiated with a laser in Quan Baichang scattering arrays Schematic diagram；

Fig. 5 is the structural representation of second of embodiment of the utility model excitation light source system；

Fig. 6 is the structural representation of the third embodiment of the utility model excitation light source system；

Fig. 7 is that the third embodiment of the utility model excitation light source system is irradiated with a laser in Quan Baichang scattering arrays Schematic diagram；

Fig. 8 is the structural representation of the 4th kind of embodiment of the utility model excitation light source system.

Embodiment

It should be appreciated that specific embodiment described herein is not used to limit this only to explain the utility model Utility model.

Embodiment one

Refer to shown in Fig. 3, be that a kind of structure of excitation light source system of the utility model the first embodiment offer is shown It is intended to.The present embodiment includes three kinds of excitation sources (301,302,303), collection system, relay system 305, the first lenticule battle array Row 306, the second microlens array 309, spatial light modulator 307, scattering powder array 308, image-forming objective lens 310.

Wherein excitation source excites including sending the red laser 301 of 638nm red exciting lights, sending 520nm greens The green (light) laser 302 of light and the blue laser 303 for sending 445nm blue excitation lights.

First microlens array 306 and the second microlens array 309 include playing the multiple micro- of convergence effect of light respectively Lens unit, scattering powder array 308 include multiple scattering powder units.

After collection system is focused to each exciting light, each exciting light is burnt in the focus composition one first that collection system is formed Plane 30, i.e. collection system dissipate after each exciting light collection caused by excitation source is converged at into the first focal plane 30, specifically Include form the first focal plane with excitation source multiple collecting lenses 304 correspondingly, the focus of multiple collecting lenses 304 30.Collection system forms the differentiation of EDS maps on the first focal plane 30 in the exciting light warp that different excitation sources are sent.Wherein, Three kinds of excitation sources are located along the same line along projection of the optical axis direction in the display system.Specifically in present embodiment In, excitation source is located parallel on the same straight line of the first focal plane 30.The initial optical path of wherein three excitation sources is mutual It is parallel.Corresponding, collecting lens 304 is also three, and three collecting lenses 304 are located along the same line.Certainly, optional In the other embodiment selected, multigroup excitation source can also be set, and matched multiple collecting lenses are set, and It can implement.

Relay system 305 is located in the exciting light light path after collecting lens 304, and relay system 305 intersects including exciting light The second focal plane 31 converged, the repeated system 305 of exciting light that different excitation sources are sent form angle on the second focal plane 31 The differentiation of distribution.I.e. the repeated system 305 of optics expansion amount is converted into second Jiao by the differentiation of the EDS maps of the first focal plane 30 The differentiation of the angle distribution of plane 31.Because three kinds of excitation sources are different relative to the visual field of light relay system 305, therefore work as and excite When light source images in 31, although the exciting light light of three kinds of colors overlaps, different incident lights are different from the angle of optical axis, i.e., The differentiation of angle distribution.After the convergence of each lenticule unit in the first microlens array 306, by spatial modulator 307 modulation, converge at the different scattering powder units of scattering powder array 308.Wherein, spatial light modulator 307 includes being used to adjust Multiple pixel cells of different exciting lights are made, scatter the scattering powder unit in powder array 308 and the picture in spatial light modulator 307 Plain unit corresponds.

Different exciting lights is scattered in the form of lambert's light respectively after the scattering of each scattering powder unit, then through second After each lenticule unit in microlens array 309 is collected, finally projects to and be imaged on image-forming objective lens 310, and pass through Image-forming objective lens 310 are crossed to project in exterior screen.Imaging on image-forming objective lens 310 includes multiple pixels, wherein each scattering Powder unit scatters a kind of exciting light, is correspondingly formed a sub- pixel.

Three sub- pixels on same straight line form a pixel, and each pixel branch includes RGB (RGB) three Sub-pixel point.Specifically in the present embodiment, because each pixel has individual tri- signal values of RGB in projected picture, therefore In such a system, the corresponding relation of pixel is：The corresponding three sub- pixels corresponding first of a pixel in projected picture are micro- A lenticule unit in lens array 306 corresponds to corresponding three scatterings of three pixel cells in spatial light modulator 307 Three lens units in corresponding second microlens array 309 of powder unit.Swashed as shown in figure 4, scattering powder array for complete white field The schematic diagram of light irradiation, three RGBs scattering powder point of the pixel from row to arrangement are formed.

In present embodiment, spatial light modulator 307 can be any one in LCD, DMD or LCOS, the present embodiment Be by taking transmission type LCD as an example, due to LCD it is generally necessary to be modulated to polarised light, and inherently a kind of linearly polarized light of laser, Polarization converter device is not needed, therefore improves optics utilization rate, and exciting light is after the outgoing of the second microlens array 309 Camera lens is directly entered, reduces the rear cut-off distance of camera lens.

Embodiment two

Present embodiment is the improvement made on the basis of first embodiment, in the first embodiment, reference picture 4, because three RGBs scattering powder unit of the pixel from row to arrangement is formed, therefore spatial light tune is sacrificed to a certain extent The resolution ratio of device processed, therefore embodiment two is proposed, shown in reference picture 5, it is roughly the same with the first embodiment principle, difference It is the structure of excitation source and collection system.

The spectroscope that present embodiment is opened using sequential adjusts the exciting light passed through.Specifically, including excitation source (501,502,503), collection system, relay system 505, the first microlens array 506, the second microlens array 509, spatial light Modulator 507, scattering powder array 508, image-forming objective lens 510.Collection system include collecting lens 504 and light splitting eyeglass (512, 513)。

Excitation source (501,502,503) includes sending the red laser 501 of 638nm red exciting lights, sends 520nm The green (light) laser 502 of green exciting light and the blue laser 503 for sending 445nm blue excitation lights.

Wherein, the initial optical path for the exciting light that three kinds of excitation sources are sent is not parallel, is mutual specifically in the present embodiment Three perpendicular excitation light paths, light splitting eyeglass include being arranged on anti-blue light in the blue laser light path yellow He of eyeglass 512 thoroughly Be arranged in red laser light path it is counter be popular in blue or green eyeglass 513, the exciting light of different excitation sources is by the anti-of light splitting eyeglass Penetrate or lens light path overlaps, and the first focal plane 50 of collecting lens is converged at through collecting lens.Certainly, it is selectable other In embodiment, the quantity of spectroscopical quantity and excitation source is also not necessarily limited to this, as long as closing light can be played using spectroscope Effect, be to implement.

It is right respectively by opening the spatial light modulator 507 of excitation source 501,502,503 according to projection signal's sequential Rgb signal is modulated, and then causes the incident same scattering powder unit of exciting light of modulated different colours, through its scattering After eliminating coherence, be time-multiplexed the pixel formed in projected picture.

Specifically in the present embodiment, the corresponding relation of pixel is：A pixel corresponding first is micro- in projected picture The corresponding scattering powder unit of pixel cell in the corresponding spatial light modulator of a lenticule unit in lens array 506 A lens unit in corresponding second microlens array 509.

Embodiment three

Present embodiment is the improvement made on the basis of first embodiment, in the first embodiment, reference picture 4, because three RGBs scattering powder unit of the pixel from row to arrangement is formed, the length-width ratio of each pixel it is excessive (length-width ratio= 3), therefore, present embodiment adjusts the arrangement of rgb pixel by changing the arrangement of excitation source.

Shown in reference picture 6 and Fig. 7, it is roughly the same with the first embodiment principle, and difference is the row of excitation source Cloth.

Specifically, including excitation source (601,602,603), collecting lens 604, relay system 605, the first lenticule battle array Row 606, the second microlens array 609, spatial light modulator 607, scattering powder array 608, image-forming objective lens 610.

Wherein, multiple excitation sources are arranged in a matrix fashion along projection of the optical axis direction in the display system, specifically In the present embodiment, multiple excitation sources also are located on same plane, and because green glow plays a decisive role to brightness, green glow swashs The quantity of light device 602 is the quantity sum of red laser 601 and blue laser 603, and any two green (light) laser 602 is not It is adjacent.Shown in reference picture 6, in the present embodiment, excitation source is arranged for the mode of 2*2 arrays.Green (light) laser 602 is two Individual, blue laser 603 respectively has one with red laser 602, and corresponding, adjacent four sub- pixels form a pixel Point, each pixel branch include a red sub-pixel point, a blue subpixels point and two green sub-pixels points.Work as throwing Shadow entirely white field picture when, the rgb pixel distribution at scattering powder array 608 is as shown in Figure 7.The corresponding relation of pixel is：Shadowgraph A lenticule unit in corresponding corresponding first microlens array 606 of four sub- pixels of a pixel in face is corresponding empty Between four lens in corresponding corresponding second microlens arrays 609 of four scattering powder units of four pixel cells in optical modulator Unit.It can be seen that in the present embodiment, the length-width ratio of pixel is 1:1, solve that length-width ratio in first embodiment is excessive to ask Topic, has more preferable Consumer's Experience.

Example IV

Present embodiment is the improvement made on the basis of first embodiment, in the present embodiment, without setting Collection system, but by setting different angles by exciting light is former, using the angle of different colours exciting light be distributed it is different and then The EDS maps being converted at scattering powder array.

Specifically, as shown in figure 8, including excitation source (801,802,803), relay system 805, the first lenticule battle array Row 806, the second microlens array 809, spatial light modulator 807, scattering powder array 808, image-forming objective lens 810.

Excitation source, microlens array 806, spatial light modulator 807, the and of relay system 805 are followed successively by along optical axis direction Scatter powder array 808, wherein excitation source includes the first plane 80 of three kinds of exciting lights convergences, different excitation sources with optical axis Different incidence angles is converged in the first plane 80, and the first plane 80 is identical with the distance of optical axes crosspoint to each excitation source.

Specifically, red laser 801, green (light) laser 802 are located at and the first plane 80 and light with blue laser 803 On the equidistant same plane of intersection point of axle.Wherein red laser 801, green (light) laser 802 and blue laser 803 and light Angle between axle is differed, and specifically in the present embodiment, green (light) laser 802 is arranged on optical axis, i.e., is pressed from both sides with optical axis Angle is 0 °, and red laser 801 and blue laser 803 are symmetrical arranged with respect to optical axis.What different excitation sources were sent excites Light convergence is again in the first plane 80.

Each excitation source is arranged to different shooting angles, and the light beam of different exciting lights weight at the first plane 80 Close, but made a distinction by angular distribution.After microlens array 806, etendue is by the angle on the first focal plane 80 The differentiation of distribution is converted into the differentiation of the EDS maps in spatial light modulator 807, and the exciting light of different angle distributions converges at space The different unit of optical modulator 807, spatial light modulator receive vision signal and exciting light are modulated.Relay system 805 will Spatial light modulator 807 images in the surface of scattering powder array 809, and passes through the projection imaging of projection objective 810.

The situation of prior art is different from, the utility model provides a kind of excitation light source system and uses the excitation source The projector equipment of system, without devices such as the colour wheel using existing product and square rods, by setting relay system, lenticule battle array Row, spatial light modulator and scattering powder array so that each exciting light is incident to scattering powder array simultaneously through spatial light modulator modulation Imaging is emitted after microlens array is collected after the scattering powder array scattering, color is realized and brightness uniformity is higher Illumination, there is good Consumer's Experience.

Embodiment of the present utility model is the foregoing is only, not thereby limits the scope of the claims of the present utility model, it is every The equivalent structure or equivalent flow conversion made using the utility model specification and accompanying drawing content, or be directly or indirectly used in Other related technical areas, similarly it is included in scope of patent protection of the present utility model.

Claims (18)

1. a kind of excitation light source system, it is characterised in that the excitation light source system includes：Multiple excitation sources, relay system, Microlens array, spatial light modulator and display system, wherein,

The excitation source includes at least one green (light) laser for sending green exciting light, at least one sends red exciting light Red laser and at least one blue laser for sending blue excitation light；

The relay system is located in the light path of the exciting light, each exciting light sent for collecting excitation source；

The microlens array includes playing the first lenticule battle array that convergence respectively excites light action before spatial light modulator Row and the second microlens array, first microlens array and second microlens array include multiple lenticule units；

The spatial light modulator is used to modulate each exciting light, and each exciting light is through described in the first microlens array incidence Spatial light modulator；

The display system is scattering powder array, for being scattered to each exciting light；

Each exciting light is incident to the scattering powder array through spatial light modulator modulation and scattered from the scattering powder array Imaging is emitted after being collected by second microlens array.

2. excitation light source system according to claim 1, it is characterised in that the spatial light modulator includes being used to modulate Multiple pixel cells of different exciting lights, the scattering powder array include multiple scattering powder units, the scattering powder unit and institute State pixel cell one-to-one corresponding.

3. excitation light source system according to claim 2, it is characterised in that the excitation light source system is included positioned at described It is used for the collection system for converging exciting light between excitation source and relay system.

4. excitation light source system according to claim 3, it is characterised in that the collection system is gathered to each exciting light Defocused, each exciting light forms one first focal plane in the focus that collection system is formed, and each exciting light is burnt flat described first The differentiation of EDS maps is formed on face.

5. excitation light source system according to claim 4, it is characterised in that the microlens array also includes swashing positioned at each The second microlens array in luminous light path after display system, the excitation light source system include what is set gradually along optical axis direction Excitation source, collection system, relay system, the first microlens array, spatial light modulator, scattering powder array and the second lenticule Array.

6. excitation light source system according to claim 5, it is characterised in that the collection system includes and excitation source one Multiple collecting lenses corresponding to one.

7. excitation light source system according to claim 6, it is characterised in that the green (light) laser, red laser and Blue laser along projection of the optical axis direction in the display system on the same line.

8. excitation light source system according to claim 7, it is characterised in that a pixel list of the spatial light modulator Member is correspondingly formed a pixel by a scattering powder unit, the pixel comprise at least one it is red, one it is green and one Three blue sub- pixels.

9. excitation light source system according to claim 6, it is characterised in that the green (light) laser, the red laser Device and the blue laser are arranged in a matrix fashion along projection of the optical axis direction in the display system, the green laser The quantity of device is the quantity sum of the red laser and the blue laser, and any two green (light) laser is non-conterminous.

10. excitation light source system according to claim 9 a, it is characterised in that pixel of the spatial light modulator Unit is correspondingly formed a pixel through a scattering powder unit, and the pixel comprises at least red, two green, indigo plants Four sub- pixels.

11. excitation light source system according to claim 5, it is characterised in that the collection system includes one and collected thoroughly Mirror and it is used to adjust what the light path of exciting light was opened at least two sequential of the collecting lens in exciting light light path It is divided eyeglass.

12. excitation light source system according to claim 11, it is characterised in that the light splitting eyeglass includes being arranged on blue light Anti- blue light on laser light path yellow eyeglass and be arranged in red laser light path counter be popular in blue or green eyeglass, different exciting lights thoroughly The exciting light in source overlaps by the reflection or lens light path of light splitting eyeglass, and converges at the of the collecting lens through collecting lens One focal plane.

13. excitation light source system according to claim 12 a, it is characterised in that pixel of the spatial light modulator Unit is correspondingly formed a pixel through a scattering powder unit.

14. excitation light source system according to claim 2, it is characterised in that the microlens array is also included positioned at each The second microlens array in exciting light light path after display system, the excitation light source system include setting gradually along optical axis direction Excitation source, the first microlens array, spatial light modulator, relay system, scattering powder array and the second microlens array.

15. excitation light source system according to claim 14, it is characterised in that different excitation sources are with different from optical axis The same plane that incidence angle is converged on optical axis, the plane is identical with the distance of optical axes crosspoint to each excitation source, and difference swashs It is luminous to form angle distribution on the plane, and be converted into EDS maps through the first microlens array and incide spatial light modulator Each pixel cell.

16. excitation light source system according to claim 15 a, it is characterised in that pixel of the spatial light modulator Unit is correspondingly formed a pixel by a scattering powder unit, the pixel comprise at least one it is red, one it is green and one Individual three blue sub- pixels.

17. excitation light source system according to claim 1, it is characterised in that the spatial light modulator be LCD, DMD or Any one in LCOS.

18. a kind of projector equipment, it is characterised in that including the excitation light source system as described in claim 1 to 17 any one.