CN208537826U - Near-eye display system - Google Patents

Abstract

The utility model provides a kind of near-eye display system, including image display device, array image-forming device and liquid crystal optical switch.Array image-forming device includes at least two imaging mirror surfaces, and each imaging lens face paste has can thoroughly can anti-film.Liquid crystal optical switch includes at least two sub- liquid crystal optical switches, and each imaging mirror surface is corresponding with every sub- liquid crystal optical switch.Sub- liquid crystal shutter is in open state in a branch of subgraph light corresponding with the sub- liquid crystal shutter of image display device output, and the subgraph light corresponding with the sub- liquid crystal shutter for enabling that image display device exports across sub- liquid crystal shutter is formed subgraph to be shown in human eye after being assembled by imaging mirror-reflection.After image display device has exported all subgraph light of image to be displayed, image to be displayed can be visually spliced into user in the subgraph to be shown that human eye is formed.The near-eye display system has the characteristics that big visual field, high-resolution, and relative to the near-eye display system small volume with traditional visual system.

Description

Near-eye display system

Technical field

The utility model relates to augmented reality fields, in particular to a kind of near-eye display system.

Background technique

Augmented reality (AR, Augmented Reality) is to carry out reality to real scene using dummy object or information The technology of enhancing is widely used in each field such as scientific research, military affairs, industry, game, video, education.At present mainstream be applied to increase The near-eye display system of strong reality, generallys use miniature image display as image source, and cooperate traditional visual system It realizes and enhancing is shown.It is limited to existing technology and technological level, the resolution ratio of miniature image display is difficult to improve.And And the display visual field of traditional visual system and the volume of visual system are closely related.Increase display visual field, visual light The volume of system can increase severely therewith.Therefore, the near-eye display system applied to augmented reality of mainstream has resolution ratio at present Low and visual field is small or bulky problem.

Utility model content

In view of this, the nearly eye the purpose of this utility model is to provide a kind of compact of large visual field high resolution is shown System, to solve the above problems.

To achieve the above object, the utility model provides the following technical solutions:

The utility model preferred embodiment provides a kind of near-eye display system, including image display device, array image-forming dress It sets and liquid crystal optical switch, the array image-forming device includes at least two imaging mirror surfaces, and each imaging lens face paste has can thoroughly can be anti- Film, the liquid crystal optical switch include at least two sub- liquid crystal optical switches, and each imaging mirror surface is corresponding with every sub- liquid crystal optical switch；

Described image display device is used to be sequentially output at least two beam subgraph light of image to be displayed, wherein every width Image to be displayed includes at least two subgraphs to be shown, and every subgraph to be shown is corresponding with every beam subgraph light, every beam Subgraph light is corresponding with every sub- liquid crystal shutter；

The imaging mirror surface is used to carry out reflection convergence to incident subgraph light；

The sub- liquid crystal shutter is used in a branch of subgraph corresponding with the sub- liquid crystal shutter of described image display device output Open state is in when as light, the subgraph light corresponding with the sub- liquid crystal shutter for making that described image display device exports is by institute Subgraph to be shown can be formed in human eye across the sub- liquid crystal shutter after imaging mirror-reflection is assembled by stating；

The sub- liquid crystal shutter is also used to export in described image display device a branch of not corresponding with the sub- liquid crystal shutter It is in close state when subgraph light；

After described image display device has exported all subgraph light of image to be displayed, each sub- liquid is passed through Crystalline substance switch can visually be spliced into the image to be displayed in user in the subgraph to be shown that human eye is formed；

Real world light passes through the array image-forming device and liquid crystal optical switch enters human eye and forms ambient image.

Optionally, described image display device includes light source module group and image-display units, and the light source module group includes shining Mingguang City source and beam shaping bundling device, the beam shaping bundling device include collimator and extender shaping component and combined beam unit；

The lighting source, for providing multi beam illuminating ray；

The collimator and extender shaping component, for carrying out collimator and extender shaping to every beam illuminating ray；

The combined beam unit, for synthesizing the light beam after the collimator and extender shaping component collimator and extender Shape correction Single beam；

Described image display unit, the energy of the single beam for being exported to the combined beam unit be modulated with formed to Show the image light of information.

Optionally, described image display device includes light source module group and scanning means；

The light source module group, for providing collimation light pencil；

The scanning means, the light for being emitted to the light source module group carry out high speed deflection to form image light.

Optionally, the scanning means is MEMS scanning means.

Optionally, described image display device includes light source module group, polarization spectro component and image-display units, the light Source mould group includes lighting source and collimator and extender shaping component；

The lighting source, for providing illuminating ray；

The collimator and extender shaping component, for carrying out collimator and extender shaping to the illuminating ray；

The polarization spectro component, it is vertical that non-polarized light for collimator and extender shaping component outgoing is divided into two beams Line polarisation, wherein P polarisation passes through completely, and S polarisation is reflected with 45 degree of angles；

Described image display unit, for carrying out light energy to S-polarization light beam according to the gray scale of subgraph to be shown at this time Modulation, is converted to P polarization light beam through the modulated light beam of described image display unit, P polarization light beam is again passed through polarization spectro Enter in array image-forming device after component.

Optionally, described image display device further includes light orientation element, and the light orientation element is arranged in the collimation The emitting light path for expanding shaping component, for choosing special angle light beam.

Optionally, the near-eye display system further includes controllable back layer.

Optionally, the imaging mirror surface is diffraction plane or continuous curved surface.

Optionally, the energy of the subgraph light corresponding with each sub- liquid crystal shutter of described image display device output with Its corresponding sub- liquid crystal shutter increases away from image display device distance and is increased.

Optionally, the reflectivity of the imaging mirror surface increases along the direction far from image display device.

Near-eye display system provided by the utility model is by opening image display device, array image-forming device and liquid crystal light The ingenious integrated and design closed, is sequentially output at least two beam subgraph light of an image to be displayed, passes through each imaging mirror surface Reflection, which is focused at human eye formation subgraph to be shown corresponding with every beam subgraph light, to be made using persistence of vision effect in people Eye-shaped at subgraph to be shown can visually be spliced into image to be displayed in user.Therefore, the view of the near-eye display system Rink corner is equal to the sum of the field angle for all imaging mirror surfaces that array image-forming device includes.Also, point of every subgraph to be shown Resolution can resolution ratio that is identical and being equal to image to be displayed.Therefore the near-eye display system have big view field image show it is same When there is high-resolution, and relative to the near-eye display system volume applied to augmented reality with traditional visual system It is smaller.

Detailed description of the invention

It, below will be to use required in embodiment in order to illustrate more clearly of the technical solution of the utility model embodiment Attached drawing be briefly described.It should be appreciated that the following drawings illustrates only some embodiments of the utility model, therefore should not be by Regard the restriction to range as, for those of ordinary skill in the art, without creative efforts, may be used also To obtain other relevant attached drawings according to these attached drawings.

Fig. 1 is a kind of block diagram of near-eye display system provided by the embodiment of the utility model.

Fig. 2 is the structural schematic diagram of near-eye display system in an embodiment.

Fig. 3 is the structural schematic diagram of near-eye display system in another embodiment.

Fig. 4 is the light path schematic diagram that near-eye display system shown in Fig. 2 shows the first subgraph to be shown.

Fig. 5 is the light path schematic diagram that near-eye display system shown in Fig. 2 shows the second subgraph to be shown.

Fig. 6 is the light path schematic diagram that near-eye display system shown in Fig. 2 shows third subgraph to be shown.

Fig. 7 is the light path schematic diagram that near-eye display system shown in Fig. 2 shows image to be displayed.

Fig. 8 is the structural schematic diagram of near-eye display system in another embodiment.

Fig. 9 is the structural schematic diagram of near-eye display system in another embodiment.

Figure 10 is the structural schematic diagram of near-eye display system in another embodiment.

Icon: 1- near-eye display system；10- image display device；30- array image-forming device；50- liquid crystal optical switch；31- Mirror surface is imaged；51- liquid crystal optical switch；11- light source module group；13- image-display units；111- lighting source；113- light beam is whole Shape bundling device；1111- red LED light source；1112- green LED light source；1113- blue led light source；1131- collimator and extender shaping Component；1133- combined beam unit；11311- the first collimator and extender shaping unit；11312- the second collimator and extender shaping unit； 11313- third collimator and extender shaping unit；Mirror surface is imaged in 311- first；Mirror surface is imaged in 312- second；313- third imaging lens Face；The sub- liquid crystal optical switch of 511- first；The sub- liquid crystal optical switch of 512- second；The sub- liquid crystal optical switch of 513- third；15- scanning dress It sets；17- collimation lens；18- light orientation element；19- polarization spectro component；The controllable back layer of 70-.

Specific embodiment

The following will be combined with the drawings in the embodiments of the present invention, carries out the technical scheme in the embodiment of the utility model Clearly and completely describe.Obviously, described embodiment is only a part of the embodiment of the utility model, rather than all Embodiment.The component of the utility model embodiment being usually described and illustrated herein in the accompanying drawings can be matched with a variety of different It sets to arrange and design.

Therefore, requirement is not intended to limit to the detailed description of the embodiments of the present invention provided in the accompanying drawings below The scope of the utility model of protection, but it is merely representative of the selected embodiment of the utility model.Reality based on the utility model Apply example, those skilled in the art's every other embodiment obtained without making creative work belongs to The range of the utility model protection.

It should also be noted that similar label and letter indicate similar terms in following attached drawing, therefore, once a certain Xiang Yi It is defined in a attached drawing, does not then need that it is further defined and explained in subsequent attached drawing.In the utility model In description, term " first ", " second ", " third ", " the 4th " etc. are only used for distinguishing description, and should not be understood as only or imply Relative importance.

Near-eye display system 1 provided by the embodiment of the utility model, can be applied to HMD (HeadMount Display, Wear-type visual device), the augmented realities equipment such as intelligent glasses, herein with no restrictions.

Referring to FIG. 1, Fig. 1 is a kind of block diagram of near-eye display system 1 provided by the embodiment of the utility model.It should Near-eye display system 1 includes image display device 10, array image-forming device 30 and liquid crystal optical switch 50.The array image-forming device 30 include at least two imaging mirror surfaces 31, each imaging mirror surface 31 post can thoroughly can anti-film, the liquid crystal optical switch 50 is including extremely Few two sub- liquid crystal optical switches 51, each imaging mirror surface 31 are corresponding with every sub- liquid crystal optical switch 51.

Described image display device 10 is used to be sequentially output at least two beam subgraph light of image to be displayed.Wherein, often Width image to be displayed includes at least two subgraphs to be shown, and every subgraph to be shown is corresponding with every beam subgraph light.Often Beam subgraph light is corresponding with every sub- liquid crystal shutter.Pair image to be displayed is the virtual image that near-eye display system 1 is shown, i.e., The virtual display of the artificial additional information of real world.In order to improve display effect, the resolution of every subgraph to be shown Rate can be identical.And the size of every subgraph to be shown can be the same or different.

The imaging mirror surface 31 is used to carry out reflection convergence to incident subgraph light.Since each imaging mirror surface 31 pastes Have can thoroughly can anti-film, therefore the imaging mirror surface 31 be also used to carry out incident subgraph light across, can continue to Next imaging mirror surface 31 transmits.

The sub- liquid crystal shutter is used to export a branch of son corresponding with the sub- liquid crystal shutter in described image display device 10 Open state is in when image light, the subgraph light corresponding with the sub- liquid crystal shutter for exporting described image display device 10 Subgraph to be shown can be formed in human eye by passing through the sub- liquid crystal shutter after being assembled by the imaging mirror surface 31 reflection.The sub- liquid Crystalline substance switch be also used to described image display device 10 export it is a branch of with the sub- liquid crystal shutter not corresponding subgraph light when at In closed state, the subgraph light not corresponding with the sub- liquid crystal shutter exported to avoid described image display device 10 is by institute It states and enters human eye across the sub- liquid crystal shutter after the imaging reflection of mirror surface 31 is assembled.Wherein, the sub- liquid crystal shutter can be liquid A part of crystal light shutter 50 is also possible to an independent small size liquid crystal optical switch 50.With the development of technology, when electroluminescent When the switching rate of electro-chromic switch reaches liquid crystal optical switch 50, can also with electrochromism switch in place liquid crystal optical switch 50 and/ Or sub- liquid crystal optical switch 51.

After described image display device 10 has exported all subgraph light of image to be displayed, each son is passed through Liquid crystal shutter can visually be spliced into the image to be displayed in user in the subgraph to be shown that human eye is formed.Specific implementation When, every figure to be shown of frequency and output of every beam subgraph light can be exported by adjusting described image display device 10 The time interval of picture, and cooperate the switch state for adjusting every sub- liquid crystal shutter, utilize persistence of vision principle, so that it may so as to pass through Each sub- liquid crystal shutter can visually be spliced into the figure to be shown in user in the subgraph to be shown that human eye is formed Picture.

Real world light passes through the array image-forming device 30 and liquid crystal optical switch 50 enters human eye and forms environment Image.

Near-eye display system 1 provided by the embodiment of the utility model passes through to image display device 10, array image-forming device 30 and liquid crystal optical switch 50 ingenious integrated and design, be sequentially output at least two beam subgraph light of an image to be displayed, lead to It crosses each reflection of imaging mirror surface 31 and is focused at human eye formation subgraph to be shown corresponding with every beam subgraph light, utilize vision Residual effect enables the subgraph to be shown formed in human eye to be visually spliced into image to be displayed in user.Therefore, this is close The field angle of eye display system 1 is equal to the sum of the field angle for all imaging mirror surfaces 31 that array image-forming device 30 includes.Also, it is every The resolution ratio of subgraph to be shown can resolution ratio that is identical and being equal to image to be displayed.Therefore the near-eye display system 1 has There is high-resolution while big view field image display, and be applied to augmented reality relative to traditional visual system Near-eye display system small volume.

Since image display device 10, the structure of array image-forming device 30 and liquid crystal optical switch 50 and set-up mode can have It is a variety of.Therefore, based on above-mentioned utility model conceive, the specific structure of near-eye display system 1 may be, but not limited to, as Fig. 2, Shown in Fig. 3, Fig. 8, Fig. 9 and Figure 10.It should be understood that for ease of description, Fig. 2, Fig. 3, Fig. 8, Fig. 9 and nearly eye shown in Fig. 10 are shown System 1 is presented in the form of monocular.Those skilled in the art can according to fig. 2, Fig. 3, Fig. 8, Fig. 9 and structure shown in Fig. 10 Release structure when near-eye display system 1 is binocular.

As shown in Fig. 2, Fig. 2 is the structure chart of near-eye display system 1 in an embodiment.Image display device 10 includes light Source mould group 11 and image-display units 13.Light source module group 11 includes lighting source 111 and beam shaping bundling device 113.

Lighting source 111 can be using laser light source, LED light source etc..Optionally, in the present embodiment, the illumination light Source 111 is LED light source, which may include red LED light source 1111, green LED light source 1112 and blue led light source 1113.In another embodiment, the color of each LED can be configured according to actual needs in LED light source, to meet reality The needs of border situation, herein with no restrictions.

Beam shaping bundling device 113 is set in the optical path of lighting source 111, the light for issuing to lighting source 111 Beam processing is closed in the shaping of Shu Jinhang collimator and extender.Optionally, in the present embodiment, beam shaping bundling device 113 includes that collimation expands Beam shaping component 1131 and combined beam unit 1133.Collimator and extender shaping component 1131 includes the first collimator and extender shaping unit 11311, the second collimator and extender shaping unit 11312 and third collimator and extender shaping unit 11313.Wherein, the first collimator and extender The light beam that shaping unit 11311 is used to issue red LED light source 1111 carries out collimator and extender Shape correction.Second collimator and extender The light beam that shaping unit 11312 is used to issue green LED light source 1112 carries out collimator and extender Shape correction.Third collimator and extender The light beam that shaping unit 11313 is used to issue blue led light source 1113 carries out collimator and extender Shape correction.Under normal conditions, First collimator and extender shaping unit 11311, the second collimator and extender shaping unit 11312 and third collimator and extender shaping unit 11313 alignment precision may be required in several milliradians.Combined beam unit 1133 will be for that will pass through the first collimator and extender shaping list First 11311, second collimator and extender shaping unit 11312 and 11313 collimator and extender Shape correction of third collimator and extender shaping unit Light beam afterwards synthesizes single beam.Optionally, combined beam unit 1133 is x-cube type light-combining prism.

Image-display units 13 form the figure of information to be displayed for the energy of the light of the offer of modulated light source mould group 11 As light.Image-display units 13 can be reflective, or transmission-type.Optionally, in the present embodiment, scheme As display unit 13 is transmission-type.For example, image-display units 13 are transmission-type LOCS (Liquid Crystal on Silicon, liquid crystal on silicon) display source.

Array image-forming device 30 includes at least two imaging mirror surfaces 31, and each imaging mirror surface 31 posts can thoroughly can anti-film.Institute Imaging mirror surface 31 is stated to be used to carry out reflection convergence to incident subgraph light.The imaging mirror surface 31, which has, converts plane wave For the function of spherical wave.It can be continuous curved surface or diffraction plane that mirror surface 31, which is imaged,.Optionally, in the present embodiment, at As mirror surface 31 is continuous curved surface.It is clear that imaging mirror surface 31 can be the continuous curved surface of optical body, multiple optics are real Body gluing forms array image-forming device 30, as shown in Figure 2.Mirror surface 31 or curved mirror is imaged, multiple curved mirrors arrange shape At array image-forming device 30, as shown in Figure 3.

Referring to Fig. 2 or Fig. 3, in the present embodiment, array image-forming device 30 includes three imaging mirror surfaces 31, point It is not denoted as the first imaging mirror surface 311, second imaging mirror surface 312 and third imaging mirror surface 313.Correspondingly, liquid crystal optical switch 50 wraps Three sub- liquid crystal optical switches 51 are included, are denoted as the first sub- liquid crystal optical switch 511, the second sub- liquid crystal optical switch 512 and third respectively Liquid crystal optical switch 513.

It is as follows that the near-eye display system 1 that present embodiment provides carries out the process that a virtual image is shown: a width is waited for Display image is divided into three subgraphs to be shown in the horizontal direction, is denoted as the first subgraph to be shown, the second son to be shown respectively Image and third subgraph to be shown.Firstly, referring to Fig. 4, image display device 10 is exported according to the first subgraph to be shown A branch of subgraph light, the first sub- liquid crystal shutter are in open state, and the second sub- liquid crystal shutter and the sub- liquid crystal shutter of third, which are in, to close Closed state.After the beam subgraph light is assembled by the first imaging reflection of mirror surface 311, formed across the first sub- liquid crystal shutter in human eye First subgraph to be shown.Since the second sub- liquid crystal shutter and the sub- liquid crystal shutter of third are in close state, then first is being formed When subgraph to be shown, across the first imaging mirror surface 311 by the light after the second imaging reflection convergence of mirror surface 312 and across first The light after mirror surface 311 and the second imaging mirror surface 312 are assembled by the third imaging reflection of mirror surface 313, which is imaged, will not enter human eye, make At interference.Secondly, referring to Fig. 5, image display device 10 exports a branch of subgraph light according to the second subgraph to be shown, the Two sub- liquid crystal shutters are in open state, and the first sub- liquid crystal shutter and the sub- liquid crystal shutter of third are in close state.The beam subgraph Light a part is transmitted after being assembled by the first imaging reflection of mirror surface 311 to the first sub- liquid crystal shutter, and another part passes through the first one-tenth As mirror surface 311.Subgraph light a part across the first imaging mirror surface 311 is worn after the second imaging reflection convergence of mirror surface 312 It crosses the second sub- liquid crystal shutter and forms the second subgraph to be shown in human eye, another part passes through the second imaging mirror surface 312 to third Mirror surface 313 is imaged to transmit.The subgraph light a part transmitted to third imaging mirror surface 313 is reflected by third imaging mirror surface 313 It assembles to the sub- liquid crystal shutter transmission of third, another part passes through third and mirror surface 313 is imaged.Similarly, due to the first sub- liquid crystal shutter It is in close state with the sub- liquid crystal shutter of third, therefore when forming the second subgraph to be shown, by the first imaging 311 He of mirror surface The light after the reflection of mirror surface 313 is assembled, which is imaged, in third will not enter human eye, interfere.Finally, referring to Fig. 6, image is shown Device 10 exports a branch of subgraph light according to third subgraph to be shown, and the sub- liquid crystal shutter of third is in open state, the first son Liquid crystal shutter and the second sub- liquid crystal shutter are in close state.Similarly, a part of of the beam subgraph light can pass through first Mirror surface 311 and the second imaging mirror surface 312 is imaged by after the third imaging reflection convergence of mirror surface 313, passes through the sub- liquid crystal shutter of third and exists Human eye forms third subgraph to be shown.Since the first sub- liquid crystal shutter and the second sub- liquid crystal shutter are in close state, In formation third subgraph to be shown, the light after being assembled by the first imaging mirror surface 311 and the second imaging reflection of mirror surface 312 is not Human eye can be entered, interfered.

In above process, can be exported by adjusting described image display device 10 frequency of every beam subgraph light with And the time interval of the every width image to be displayed of output, and cooperate the switch state for adjusting every sub- liquid crystal shutter, it is residual using vision Stay principle, so that it may so that it is to be shown to pass through the first subgraph to be shown, second that each sub- liquid crystal shutter formed in human eye Subgraph and third subgraph to be shown can visually be spliced into the image to be displayed in user, as shown in Figure 7.

From the above process as can be seen that image display device 10, which exports subgraph light, is passing through imaging mirror surface 31 to next When a imaging mirror surface 31 transmits, energy can decay.Therefore, in order to avoid the first subgraph to be shown, the second subgraph to be shown It is different with third subgraph energy to be shown, mirror surface 312 is imaged in the first imaging mirror surface 311, second and mirror surface 313 is imaged in third Reflectivity it is identical when, image display device 10 can be made according to the energy of the subgraph light of the first subgraph to be shown output The energy of the subgraph light measure, exported according to the second subgraph to be shown, the subgraph exported according to third subgraph to be shown As the energy of light is sequentially increased.Or in image display device 10 according to the subgraph light of the first subgraph output to be shown Energy, according to the energy of the subgraph light of the second subgraph to be shown output and according to third subgraph output to be shown When the energy of subgraph light is equal, make the first imaging mirror surface 311, second imaging mirror surface 312 and third that the anti-of mirror surface 313 be imaged The rate of penetrating is sequentially increased, in order to avoid the first subgraph, the second subgraph to be shown and third subgraph energy difference to be shown to be shown. That is, the energy of each subgraph to be shown to avoid image to be displayed is different, image display device 10 can be made defeated The energy of subgraph light beam corresponding with each sub- liquid crystal shutter out, which is shown with corresponding sub- liquid crystal shutter away from image, to be filled 10 distances are set to increase and increase or increase the reflectivity of the imaging mirror surface 31 along the direction far from image display device 10.

As shown in figure 8, Fig. 8 is the structure chart of near-eye display system 1 in another embodiment.It is similar with Fig. 2, it is different Be: image display device 10 does not use image-display units 13, and uses scanning means 15.Accordingly, image display device 10 It is slightly different in the optical parameter and structure and Fig. 2 of middle light source module group 11.

Optionally, light source module group 11 includes lighting source 111 and beam shaping bundling device 113.Beam shaping bundling device 113 Including collimator and extender shaping component 1131 and combined beam unit 1133.Lighting source 111 can use laser light in light source module group 11 Source, LED light source etc..Collimator and extender shaping component 1131 is for exporting collimation light pencil.Optionally, collimator and extender shaping component 1131 can be made of focal length collimating mirror, short focus focus lamp, aperture and short focus collimating mirror.The light that lighting source 111 exports Beam is converged to hot spot again after focal length collimating mirror and short focus focus lamp, and aperture takes center to the hot spot after convergence Domain filters out spot side-lobe, obtains the small light spot that energy is concentrated, and last small light spot is again Energy distribution by short focus collimating mirror collimation Uniform collimation light pencil.When lighting source 111 exports polychromatic light, beam shaping bundling device 113 further includes combined beam unit 1133.Combined beam unit 1133 can be set on the emitting light path of collimator and extender shaping component 1131, expand for collimation whole The light beam that shape component 1131 exports carries out conjunction beam；Or be arranged on the emitting light path of lighting source 111, for lighting unit The light beam of output carries out conjunction Shu Houzai and exports to collimator and extender shaping component 1131.

Scanning means 15 is arranged on the emitting light path of light source module group 11, and the light for being emitted to light source module group 11 carries out High speed deflection is to form image light.Scanning means 15 can select the device with scanning function in well-known technique.For example, The scanning means 15 can be MEMS scanning means, piezoelectric ceramics fibre-optic scanner, Controlled Crystal scanning means etc..It is optional Ground, in the present embodiment, scanning means 15 are MEMS scanning means.MEMS scanning means can be scanned by a two dimension MEMS Galvanometer composition or two one-dimensional MEMS scanning galvanometer compositions.Light source module group 11 (is sent to user's eye according to image to be sent Virtual image in eyeball) color and gray scale require be modulated after light be input to MEMS scanning means.MEMS scanning dress Setting can be deflected according to driving signal, namely realize the purpose of output image light by scanning this process.

Optionally, described image display device 10 further includes collimation lens 17.The collimation lens 17 is set to scanning dress It sets on 15 emitting light path, carries out collimation processing for the emergent ray to scanning means 15, enable light after treatment It is entered in a manner of approximately parallel in subsequent array image-forming device 30.

Similarly, array image-forming device 30, can also be using array image-forming in Fig. 3 other than using structure as shown in Figure 8 The structure of device 30, i.e. imaging mirror surface 31 or curved mirror, multiple curved mirrors arrange to form array image-forming device 30.

As shown in figure 9, Fig. 9 is the structure chart of near-eye display system 1 in another embodiment.It is similar with Fig. 2, it is different It is:

Lighting source 111 is monochromatic source, such as the LED light source of green.Thus, beam shaping bundling device 113 does not include Combined beam unit 1133 only includes collimator and extender shaping component 1131.Collimator and extender shaping component 1131 is used for green LED light source 1112 light beams issued carry out collimator and extender Shape correction.Under normal conditions, since LED light source belongs to the face with certain size Light source (usually 1mm), according to law of conservation of energy, by collimator and extender shaping component 1131, treated that light beam is not exhausted Pair collimated light beam.It, can be in collimator and extender shaping component for the display resolution of the raising near-eye display system 1 of higher degree One light orientation element 18 is set on 1131 emitting light path.In present embodiment, light orientation element 18 can be angular-sensitive and spread out Penetrate element or holographic element.

Image-display units 13 be it is reflective, for example, reflective LOCS shows source.Described image display device 10 is also Including polarization spectro component 19.Vibration spectrum groupware is incident non-polarized light can be divided into the vertical line polarisation of two beams, wherein P Polarisation passes through completely, and a kind of optical element that S polarisation is reflected with 45 degree of angles.In present embodiment, polarization spectro component 19 It can be PBS prism (polarization beam splitter, polarization splitting prism).

When it is implemented, the light beam that lighting source 111 exports passes through the 1131 collimator and extender shaping of collimator and extender shaping component And after light orientation element 18 is handled, into polarization spectro component 19, S-polarization light beam reflexes to image by polarization spectro component 19 and shows Show that unit 13, image-display units 13 carry out light energy modulation, warp to S-polarization light beam according to the gray scale of subgraph to be shown at this time The modulated light beam of image-display units 13 is converted to P polarization light beam, and it is laggard that P polarization light beam is again passed through polarization spectro component 19 Enter in array image-forming device 30.

In other embodiments, above-mentioned polarization spectrum groupware can also with it is inclined can thoroughly can antiplane mirror replace. But use it is inclined can thoroughly can antiplane mirror can decay to beam energy.

Optionally, in the present embodiment, imaging mirror surface 31 is diffraction plane.Specifically, imaging mirror surface 31 can be flat Face base type binary diffraction mirror surface, the binary diffraction mirror surface can convert spherical wave for plane wave.It is clear that The diffraction plane that mirror surface 31 can be tilting prisms is imaged, multiple tilting prisms gluings form array image-forming device 30, such as Fig. 9 institute Show.Mirror surface 31 or diffraction plane mirror is imaged, multiple diffraction plane mirrors arrange to form such as Figure 10 institute of array image-forming device 30 Show.It should be noted that mirror surface 312 is imaged for the first imaging mirror surface 311, second and mirror surface 313 is imaged in third in present embodiment Tilt angle may be the same or different.Correspondingly, the first imaging mirror surface 311, second be imaged mirror surface 312 and third at As the binary diffraction pattern of mirror surface 313 may be the same or different.

Referring to Fig. 9, optionally, near-eye display system 1 further includes controllable back layer 70.The controllable back layer 70 Opacity can be become dark or opaque from clear, it is (to be shown with the virtual image for improving the display of near-eye display system 1 Image) contrast.In specific implementation process, controllable back layer 70 can be electrochromic layer.Electrochromic layer can be close to Array image-forming device 30 can also be spaced an air gap or optical material with array image-forming device 30.

From the above it can be seen that image display device 10 and array image-forming device 30 in Fig. 2, Fig. 3, Fig. 8, Fig. 9 and Figure 10 It can be combined with each other.For example, the image display device 10 in the image display device 10 and Fig. 8 in Fig. 2 is exchanged new to constitute Two kinds of near-eye display systems 1.In another example the controllable back layer 70 in Fig. 9 is respectively applied in Fig. 2, Fig. 3, Fig. 8 and Figure 10 To constitute two kinds of new near-eye display systems 1.And Fig. 2, Fig. 3, Fig. 8, Fig. 9 and near-eye display system shown in Fig. 10 1 are only Schematically.For example, increasing or decreasing the number of the imaging mirror surface 31 in Fig. 2, Fig. 3, Fig. 8, Fig. 9 and Figure 10 just to constitute newly Near-eye display system 1.In another example increase or decrease the number of the lighting source 111 in Fig. 2, Fig. 3, Fig. 8, Fig. 9 and Figure 10 just with Constitute new near-eye display system 1.

Near-eye display system 1 provided by the embodiment of the utility model passes through to image display device 10, array image-forming device 30 and liquid crystal optical switch 50 ingenious integrated and design, be sequentially output at least two beam subgraph light of an image to be displayed, lead to It crosses each reflection of imaging mirror surface 31 and is focused at human eye formation subgraph to be shown corresponding with every beam subgraph light, utilize vision Residual effect enables the subgraph to be shown formed in human eye to be visually spliced into image to be displayed in user.Therefore, this is close The field angle of eye display system 1 is equal to the sum of the field angle for all imaging mirror surfaces 31 that array image-forming device 30 includes.Also, it is every The resolution ratio of subgraph to be shown can resolution ratio that is identical and being equal to image to be displayed.Therefore the near-eye display system 1 has There is high-resolution while big view field image display, and be applied to augmented reality relative to traditional visual system Near-eye display system small volume.

Any feature disclosed in this specification (including any accessory claim, abstract and attached drawing), except non-specifically chatting It states, can be replaced by other alternative features that are equivalent or have similar purpose.That is, unless specifically stated, each feature is only It is an example in a series of equivalent or similar characteristics.

The above descriptions are merely preferred embodiments of the present invention, is not intended to limit the utility model, for this For the technical staff in field, various modifications and changes may be made to the present invention.It is all in the spirit and principles of the utility model Within, any modification, equivalent replacement, improvement and so on should be included within the scope of protection of this utility model.

Claims (10)

1. a kind of near-eye display system, which is characterized in that including image display device, array image-forming device and liquid crystal optical switch, The array image-forming device includes at least two imaging mirror surfaces, each imaging lens face paste have can thoroughly can anti-film, the liquid crystal light opens Closing includes at least two sub- liquid crystal optical switches, and each imaging mirror surface is corresponding with every sub- liquid crystal optical switch；

Described image display device is used to be sequentially output at least two beam subgraph light of image to be displayed, wherein every width waits showing Diagram picture includes at least two subgraphs to be shown, and every subgraph to be shown is corresponding with every beam subgraph light, every Shu Zitu As light is corresponding with every sub- liquid crystal shutter；

The imaging mirror surface is used to carry out reflection convergence to incident subgraph light；

The sub- liquid crystal shutter is used in a branch of subgraph light corresponding with the sub- liquid crystal shutter of described image display device output Open state is in when line, the subgraph light corresponding with the sub- liquid crystal shutter for exporting described image display device by it is described at The sub- liquid crystal shutter is passed through after assembling as mirror-reflection to form subgraph to be shown in human eye；

The sub- liquid crystal shutter is also used to export a branch of subgraph not corresponding with the sub- liquid crystal shutter in described image display device As being in close state when light；

After described image display device has exported all subgraph light of image to be displayed, opened across each sub- liquid crystal The image to be displayed can be visually spliced into user in the subgraph to be shown that human eye is formed by closing；

Real world light passes through the array image-forming device and liquid crystal optical switch enters human eye and forms ambient image.

2. near-eye display system according to claim 1, which is characterized in that described image display device includes light source module group And image-display units, the light source module group include lighting source and beam shaping bundling device, the beam shaping bundling device packet Include collimator and extender shaping component and combined beam unit；

The lighting source, for providing multi beam illuminating ray；

The collimator and extender shaping component, for carrying out collimator and extender shaping to every beam illuminating ray；

The combined beam unit, for the light beam after the collimator and extender shaping component collimator and extender Shape correction to be synthesized monochromatic light Beam；

Described image display unit, the energy of the single beam for exporting to the combined beam unit are modulated to be shown to be formed The image light of information.

3. near-eye display system according to claim 1, which is characterized in that described image display device includes light source module group And scanning means；

The light source module group, for providing collimation light pencil；

The scanning means, the light for being emitted to the light source module group carry out high speed deflection to form image light.

4. near-eye display system according to claim 3, which is characterized in that the scanning means is MEMS scanning means.

5. near-eye display system according to claim 1, which is characterized in that described image display device includes light source die Group, polarization spectro component and image-display units, the light source module group include lighting source and collimator and extender shaping component；

The lighting source, for providing illuminating ray；

The collimator and extender shaping component, for carrying out collimator and extender shaping to the illuminating ray；

The polarization spectro component, it is inclined that the non-polarized light for collimator and extender shaping component outgoing is divided into the vertical line of two beams Light, wherein P polarisation passes through completely, and S polarisation is reflected with 45 degree of angles；

Described image display unit, for carrying out light energy modulation to S-polarization light beam according to the gray scale of subgraph to be shown at this time, P polarization light beam is converted to through the modulated light beam of described image display unit, after P polarization light beam is again passed through polarization spectro component Into in array image-forming device.

6. near-eye display system according to claim 5, which is characterized in that described image display device further includes light orientation Element, the emitting light path of the collimator and extender shaping component is arranged in the light orientation element, for choosing special angle light beam.

7. near-eye display system according to claim 1-6, which is characterized in that the near-eye display system also wraps Include controllable back layer.

8. near-eye display system according to claim 1-6, which is characterized in that the imaging mirror surface is flat for diffraction Face or continuous curved surface.

9. near-eye display system according to claim 1-6, which is characterized in that the output of described image display device Subgraph light corresponding with each sub- liquid crystal shutter energy with corresponding sub- liquid crystal shutter away from image display device away from Increase from increase.

10. near-eye display system according to claim 1-6, which is characterized in that the reflection of the imaging mirror surface Rate increases along the direction far from image display device.