WO2022252507A1

WO2022252507A1 - Reflection spectral imaging system for near-to-eye display

Info

Publication number: WO2022252507A1
Application number: PCT/CN2021/132016
Authority: WO
Inventors: 李湘裔
Original assignee: 李湘裔
Priority date: 2021-06-01
Filing date: 2021-11-22
Publication date: 2022-12-08
Also published as: CN113655616B; CN113655616A

Abstract

Disclosed is a reflection spectral imaging system for near-to-eye display in the field of optical technology. The reflection spectral imaging system is composed of an image projection unit (100) and an optical lens (200) that has a reflection spectral imaging function, wherein the image projection unit (100) is an image source projection optical system including monochromatic narrow-band spectral characteristics of red (R)/green (G)/blue (G), etc.; and the optical lens (200) has an optical reflection surface pattern that matches the image projection unit (100), and is plated with an optical film (201) having a narrow-band spectral reflection imaging function. The image light output by the image projection unit (100) can be directly projected onto an inner surface of the optical lens (200), and is reflected by the optical film (201) to the retinas of human eyes for imaging to form an amplified virtual image in front of the human eyes, so as to achieve the purpose of near-to-eye display. The reflection spectral imaging system has a good adaptability to human eyes, a high imaging quality, a high display definition, a good perspective performance, and a slim and miniaturized design, and makes it easy to realize large-scale industrial production.

Description

Reflectance Spectral Imaging System for Near-Eye Displays

technical field

The invention belongs to the field of optical technology, in particular to a reflection spectrum imaging system for near-eye display.

Background technique

Since Ivan Sutherland published the paper "Ultimate Display" (Ultimate Display) in 1965, virtual reality (VR) technology has been continuously improved from concept to theory and promoted in the fields of military, aerospace, audio-visual entertainment, education, industrial design, and medicine. The application of its existence, multi-perception, and interactivity has been loved and recognized by more and more people, and the demand from all walks of life is growing day by day. With the development and progress of science and technology such as computer technology, electronic information technology, and simulation technology, virtual reality (VR) technology, augmented reality (AR) technology, and mixed reality (MR) technology are competing to develop, and the application research in related fields is extremely active. It has developed rapidly, made great progress, and has increasingly wide application scenarios, showing broad and bright development prospects.

In the application of virtual reality (VR) technology, augmented reality (AR) technology, and mixed reality (MR) technology, all involve imaging information through the retina of the human eye to form a virtual image or a simulation scene close to reality in the air, so that the application The near-eye display device achieves a good effect of fusion of presence, multi-perception and user interaction. To achieve this goal, its main technical path is to use near-eye display technology, in which the optical system and optical lenses that constitute the near-eye imaging display affect and determine Focus on the complexity of the optical system structure of the near-eye display device, the quality of the imaging display, the physiological adaptability to the user, and the comprehensive effect of the actual experience. In order to achieve the best effect of near-eye display devices, people have researched and developed many structural forms of near-eye display optical systems and optical lenses, which have been applied to related products, but so far the following common problems still exist in the existing technology: imaging The structure of the display system and lens is complicated, the adaptability to the human eye is not strong, and a vision correction device is required separately, the efficiency of light energy utilization is low, the quality of imaging display is difficult to meet the design requirements, the user experience is not good, and the processing technology is complex and large-scale manufacturing Difficulty, high manufacturing costs, etc. have hindered the large-scale manufacturing and market promotion of related technologies and products, making it difficult for them to be popularized and applied quickly.

Early near-eye display imaging optical systems and lenses are mainly composed of multi-piece structures. Although this type of structure can achieve the effect of near-eye display, due to the relatively complex structure of the optical lens, thick optical thickness, and heavy weight, it is not compatible with the human eye. The adaptability is poor, and the uncomfortable physiological reactions such as dizziness and nausea will appear after wearing for a long time, which is gradually replaced by the new structure. In order to solve the above problems and realize the thinning of the near-eye display system, people have researched and developed a variety of structural forms of near-eye display optical systems and lenses. According to published related patents and information reports, the new near-eye display imaging system and optical lenses are mainly Design and development around optical waveguide technology (including geometric optical waveguide, diffractive optical waveguide, holographic optical waveguide, etc.), free-form surface prism technology, free-form surface micro-nano optical superstructure surface technology, etc. Some of the patented technologies have been commercialized and It has been pushed to the market and promoted the development and progress of near-eye display technology, but the above-mentioned prior art still has various deficiencies that make it difficult to meet the requirements of related technological development. Taking the representative optical waveguide imaging display technology as an example, the optical waveguide lens is considered to be the key development direction of the future AR near-eye display technology due to its light and thin shape structure and high light transmittance, such as the geometric optical waveguide of Israel Lumus Arrays, "Waveguide Components and Near-Eye Display Devices" of China Huawei Technologies Co., Ltd. (application number 201910212609.8), etc., diffractive optical waveguides such as the optical waveguide patent of Microsoft's HoloLens (US9372347), and the optical waveguide patent (US2018/0052277) published by Magic Leap ) and so on are surface relief grating waveguides based on lithography technology and holographic optical waveguides based on holographic technology. Their technical paths mainly revolve around planar optical waveguides to deal with the optical problems of near-eye display systems. Coupled in, and then allocated to the fan-shaped extended exit pupil area, and finally coupled out to the human eye by the square out-coupling area. Although the near-eye display optical system and optical lenses of the optical waveguide structure have a better thinning effect, there are still the following shortcomings: Due to the loss of light energy in the process of coupling in and out of the waveguide and transmission, the light energy utilization rate of the imaging display is low, and the diffraction dispersion effect that is difficult to eliminate in the diffractive optical waveguide causes the image to produce "rainbow" phenomenon and halo, and the optical waveguide lens is general It is difficult to manufacture curved lenses suitable for human eyes due to the parallel plate structure, and the complex processing technology of optical waveguide lenses leads to high yield and low cost. Obvious deficiencies such as thinness, prism dispersion effect, and poor adaptability to the human eye; the new technology of the free-form surface micro-nano optical superstructure surface, such as the patent applied by the University of Rochester (ROCHESTER) "for virtual and augmented reality near-eye The free-form nanostructure surface of the display" (patent application number 201680028406, authorized announcement number CN107771297B, authorized announcement date 2021.04.06) mainly uses combiners, secondary mirrors, and free-form nanostructured waveguides, as described in the claims The 28 claims are all about the supergrating structure defined by the surface of the nanostructure, that is, cells with multiple superatoms and different aspect ratios. Its essence is to use the technical principle of reflective gratings. Lighter and thinner lenses, but the processing technology and process involved are more complicated, and the super grating on the surface of the nanostructure needs to be carefully protected, otherwise the fine nanostructure on the surface is not only easy to be scratched, but also slightly stained with dirt will affect the imaging display As a result, it will take time for the technology to mature.

Contents of the invention

In order to solve the deficiencies of the existing technology, the purpose of the present invention is to adopt a near-eye display reflection spectrum imaging system different from the prior art, which integrates reflection spectrum imaging, vision correction and good transparency with only one lens. The function replaces the functions that can only be realized by multi-sheet or multi-layer glued structures or other complex surface morphology structures in the prior art, and can greatly simplify the structural design of the prior art. It has the characteristics of good adaptability to human eyes, high imaging quality, high display definition, excellent perspective performance, thin and small design, easy to realize industrial scale production and relatively low manufacturing cost, and can be widely used in virtual reality (VR ), augmented reality (AR), mixed reality (MR) and other application scenarios such as smart glasses and other forms of near-eye display devices and miniaturized projection display devices, which have more practical significance for accelerating the development and application promotion of related technologies .

In order to achieve the above object, the technical solution adopted by the present invention is a reflection spectrum imaging system for near-eye display, which is characterized in that it is composed of an image projection unit (100) and an optical lens (200) with optical film reflection spectrum imaging function. ; The image projection unit (100) is red (λ _R ± δ _λR ) / green (λ _G ± δ _λG ) / blue (λ _B ± δ _λB ) / or more monochromatic yellow (λ _Y ± δ _λY ) LED, laser, OLED lighting, display, imaging optical projection system, or although it does not contain the narrow-band spectral characteristics of monochromatic light source lighting, display, and imaging, the image with the same effect is produced by adding a narrow-band filter method Optical projection system; the inner surface of the optical lens (200) has an optical surface matching the image projection unit (100) and is provided with an optical film (201) with reflection spectrum imaging function, and the outer surface is matched with the inner surface It constitutes an optical surface with vision correction function of flat light, myopia, hyperopia or astigmatism, and is equipped with a broadband anti-reflection optical anti-reflection film (202) in the visible light spectrum range, and the optical film (201) is 400nm-760nm in the visible light spectrum Within the range, there are red (λ _R ±δ _λR )/green (λ _G ±δ _λG )/blue (λ _B ±δ _λB )/or more monochrome such as yellow (λ _Y ±δ _λY ) characteristic spectrum matching the narrow-band spectral high reflection characteristics, and has the characteristics of high transmission to the rest of the spectral band; the optical anti-reflection coating (202) can improve the overall light transmittance of the optical lens, effectively eliminate the optical lens outer surface Reflected stray light interferes to improve the imaging quality of the near-eye display; the above-mentioned image projection unit (100) is installed on the side of the optical lens (200), and the output image light can be directly projected to the inner surface of the optical lens (200) covered by the optical film (201 ) is reflected to the retina of the human eye to form an enlarged virtual image in front of the human eye to achieve the purpose of near-eye display.

Further, the optical lens (200) is made of optical glass or optical plastic transparent material through grinding and polishing or molding and injection molding, and the optical film (201) and optical anti-reflection film (202) are coated by optical coating technology .

Further, when the light output by the image projection unit (100) is polarized light, the red (λ _R ±δ _λR )/green (λ _G ±δ _λG )/blue (λ _B ± δ _λB )/or more monochromatic such as yellow (λ _Y ± δ _λY ) narrow-band spectral reflectance properties designed for the corresponding polarization state.

Further, the optical lens (200) is composed of the optical film (201) combined with a material with photochromic or electrochromic function or a color filter lens with reduced light transmittance, and the optical lens (200 ) can improve the contrast and clarity of the imaging display used outdoors or in strong light environments.

Further, the optical film (201) can be plated on other transparent film substrates and pasted on the inner surface of the optical lens (200) or glued between two lenses as an interlayer.

Further, the film structure of the optical film (201) is composed of SUB (substrate)/N _M 92nm/N _L 64nm/N _M 50nm/N L 20nm/N _H 18nm/ _{N L} _184nm /N _H 112nm/N _L 42nm/N _H 19nm/N _L 30nm/N _H 139nm/N _H 38nm/N _H 106nm/N _L 27nm/N _H 107nm/N _L 56nm/N _H 23nm/N _M 44nm/N _H 89nm/N _M 187nm/ N _H 66nm/N _M 151nm/N _H 32nm/N _M 34nm/N _H 86nm/N _L 134nm/N _M 78nm/N _H 40nm/N _M 113nm/N L 12nm/ _{N M} _170nm /N _L 48nm/N _M 28nm/N _L 39nm/N _H 83nm/N _L 36nm/N _H 112nm/N L 22nm/N _H 23nm/N _M 48nm/N _H 105nm/N _M 150nm/N _H 81nm/ _{N M} _39nm /AIR(air) Composition, where N _H , N _M , N _L , are respectively high, medium and low refractive index dielectric materials in the range of 2.00-2.55, 1.60-1.85, 1.35-1.48, and each layer of the above-mentioned film structure The thickness can be adjusted within ±10%.

The film structure of the optical anti-reflection coating (202) is composed of SUB (substrate)/N _M 22nm/N _L 27nm/N _H 109nm/N _L 86nm/AIR (air), wherein N _H , N _M , N _L , respectively high, medium and low refractive index dielectric materials with a refractive index of 2.15-2.35, 1.85-2.05, 1.35-1.46.

The beneficial effect of adopting the above-mentioned technical scheme:

The difference between the present invention and the existing published patents and reports is that it adopts a completely different optical film reflection spectrum imaging system and near-eye display optical lens, and the optical lens integrates reflection spectrum imaging, vision correction and good transparency, etc. A variety of functions, one piece replaces the functions that can only be realized by multi-piece or multi-layer glued structures or other complex surface morphology structures in the prior art. It has good adaptability to the human eye, no need to configure additional vision correction devices, and uses light High rate, high imaging quality, high display definition, excellent see-through performance, lightweight and miniaturized design, easy to realize industrial scale production and relatively low manufacturing cost, etc., can be widely used in virtual reality (VR), augmented reality ( AR), mixed reality (MR) and other application scenarios of smart glasses and other forms of near-eye display devices and miniaturized projection display devices, which has more practical significance for accelerating the development and application promotion of related technologies.

The uniqueness of the present invention is manifested in: for example, compared with the optical waveguide technology, the optical film reflection spectrum imaging method is used to replace the optical waveguide structure, which requires optical coupling in and out of the waveguide and transmission process, which improves the efficiency of light energy utilization, and not only eliminates the optical waveguide The "rainbow" phenomenon and halo produced by the dispersion effect of the optical lens expand the field of view and imaging quality of the near-eye display. It can correct vision simultaneously without additional vision correction devices or other mechanisms; compared with free-form prism technology, it uses the optical film on the surface of the optical lens to reflect and image once, while the non-free-form prism structure requires multiple reflection images inside the lens, so that The shape of the lens is simpler, the optical thickness is thinner, there is no prism dispersion effect, and the viewing angle of the imaging display is larger; compared with the free-form surface nanostructure surface super grating technology, the optical thin film reflection spectrum imaging technology is used instead of complex nanometer The super-structured surface reflective grating technology overcomes the outstanding problems of low diffraction efficiency of reflective gratings, complicated surface processing technology, careful protection from dirt, limited service life, and low technology maturity.

The optical lens of the present invention adopts transparent materials such as optical glass or optical plastics to be manufactured by methods such as grinding and polishing or molding, injection molding, and the optical film and broadband anti-reflection optical anti-reflection film on its surface adopt optical coating technology methods such as physical vapor deposition. , chemical vapor deposition method, etc., not only the required raw materials are easy to obtain, but also the related process technology and equipment for large-scale manufacturing have a mature industrialization plan, which is significantly different from the processing technology required by the disclosed prior art related lenses. The large-scale production maturity, reliability, high yield rate and low cost controllability can realize rapid application and promotion.

Description of drawings

Fig. 1 is a structural representation of the present invention;

Fig. 2 is the schematic diagram of the spectral curve of the optical thin film of the present invention;

Fig. 3 is the schematic diagram of the spectral curve of the broadband anti-reflection optical anti-reflection coating of the present invention;

FIG. 4 is a schematic structural diagram of an existing optical waveguide technology;

Fig. 5 is the structural schematic diagram of existing free-form surface prism technology;

Fig. 6 is a schematic diagram of the existing free-form surface nanostructure surface technology.

Detailed ways

In order to make the technical means, creative features, goals and effects achieved by the present invention easy to understand, the present invention will be further elaborated below in conjunction with specific embodiments and accompanying drawings, but the following embodiments are only preferred embodiments of the present invention, not all . Based on the examples in the implementation manners, other examples obtained by those skilled in the art without making creative efforts all belong to the protection scope of the present invention.

The deficiencies in the prior art are described below in conjunction with the accompanying drawings.

As shown in Figure 4, the optical waveguide imaging display solution in the prior art, the light output by the image projection system is optically coupled and transmitted through the glued laminated film prism or reflection/transmission diffraction grating, etc., and the light enters and exits the waveguide and transmits The process of imaging to the retina of the human eye requires multiple reflections, which not only results in a large loss of light energy and low light efficiency utilization, but also makes it difficult to eliminate the "rainbow" phenomenon and halos caused by its inherent dispersion effect, and the parallel plate structure is similar to that of the human eye. The poor adaptability of the technical solution makes the practical experience effect of the technical solution not good.

In the free-form surface prism structure shown in Figure 5, the light output by the image projection system is imported into the retina of the human eye after multiple reflections through its special morphological structure. The optical thickness of the lens is too thick to make it thinner, and the viewing angle of the imaging display is affected. Limitation, the dispersion effect of the prism, it is difficult to adapt to the physiological structure of the human eye and so on.

Figure 6 shows the free-form surface micro-nano superstructure surface technology. The reflective grating formed by the micro-nano superstructure array on the surface of the lens reflects the projected light to the retina of the human eye for imaging. The free-form surface nano-superstructure surface grating The design and manufacture are relatively complicated, the technology maturity is not high, the manufacturing cost is relatively high, and the use requires very careful protection. There are strict requirements on the use environment and use methods, and the practical promotion is limited at this stage.

Specific embodiments of the present invention will be described below in conjunction with the accompanying drawings.

Figure 1 shows the reflection spectrum imaging system for near-eye display of the present invention, which is composed of an image projection unit 100 and an optical lens 200 with reflection spectrum imaging function, wherein the optical lens 200 integrates reflection spectrum imaging, vision correction and both Good transparency and other functions, a single lens replaces the functions that the prior art requires multiple or multi-layer glued structures or other complex surface morphology structures to achieve. The light output by the image projection unit 100 is reflected by the surface of the lens once. The retinal imaging of the human eye is introduced, and an enlarged virtual image is formed in front of the human eye to realize the purpose of near-eye display, which greatly simplifies the complex structure of the prior art.

The image projection unit 100 is an optical projection system including red (632nm±10nm)/green (520nm±10nm)/blue (450nm±10nm) LED, laser, OLED and other lighting, display and imaging optical projection systems with narrow-band spectral characteristics, or Although it does not contain the narrow-band spectral characteristics of monochromatic light source illumination, display, and imaging, it is an image optical projection system that produces the same effect by adding narrow-band filters and other methods.

The optical lens 200 is made of transparent materials such as optical glass or optical plastic through grinding, polishing, molding, injection molding, etc. The surface design of the inner surface matches the image projection unit 100, and has the ability to reflect the light output by the image projection unit 100 to the The curved surface of the retina of the human eye is plated with an optical film 201 with reflective spectrum imaging function, and the outer surface matches the first surface to form an optical surface with vision correction function (diopter is flat light, myopia, hyperopia or astigmatism) and plated There is a broadband anti-reflection AR coating 202 in the visible spectral range.

As shown in Fig. 2, the optical film 201 is within the range of 400nm-760nm of the visible light spectrum, and has both the red (632nm±10nm)/green (520nm±10nm)/blue (450nm±10nm) characteristic spectrum output by the image projection unit 100 The matched narrow-band spectrum has high reflectance characteristics, and has the characteristics of high transmission to the rest of the spectrum bands. When the light output by the image projection unit (100) is S polarized light or P polarized light or other polarized light, the red (λ _R ± δ _λR )/green (λ _G ± δ _λG ) of the optical film (201) )/blue (λ _B ±δ _λB )/or more monochrome such as yellow (λ _Y ±δ _λY ) narrow-band spectral reflection characteristics are designed according to the corresponding S polarization state or P polarization state or other polarization states.

In order to further illustrate the structural characteristics and manufacturing method of the optical film 201, a specific implementation case is given. The optical lens 200 that has been ground and polished or injection molded is transported to the magnetron sputtering vacuum coating equipment, and the film is deposited after reaching the coating conditions. The system structure is SUB (substrate)/N _M 92nm/N _L 64nm/N _M 50nm/N _L 20nm/N _H 18nm/N _L 184nm/N _{H 112nm/N L} 42nm/N _H 19nm/ _{N L} _30nm /N _H 139nm/N _L 38nm/N _H 106nm/N _L 27nm/N _H 107nm/N _L 56nm/N H 23nm/N _M 44nm/N _H 89nm/N _M 187nm/ _{N H} _66nm /N _M 151nm/N _H 32nm/ N _M 34nm/N _H 86nm/N _L 134nm/N _M 78nm/N _H 40nm/N _{M 113nm/N L} _12nm /N _M 170nm/N L 48nm/N _M 28nm/ _{N L} _39nm /N _H 83nm/N _L 36nm/N _H 112nm/N _L 22nm/N _H 23nm/N _M 48nm/N _H 105nm/N _M 150nm/N H 81nm/ _{N M} _39nm /AIR (air), the total thickness of the film layer is 3.177μ, of which N _H , N _M , N _L are respectively high, medium and low refractive index dielectric materials in the range of 2.00-2.55, 1.60-1.85, 1.35-1.48 for the sputtered film material, and the optical film coated with this film structure The schematic diagram of the spectral characteristic curve of 201 is shown in Figure 2, which achieves high reflectivity in three narrow-band spectral bands of red light (622-642nm)/green light (510-530nm)/blue light (440-460nm), and the other spectral bands High light transmittance, good anti-angle effect, suitable for matching output spectrum of red (R) 632nm / green (G) 520nm / blue (B) 450nm three-color LED or laser or OLED light-emitting display composed of image projection The unit (100) constitutes a reflection spectrum imaging near-eye display optical system.

A specific embodiment of the optical anti-reflection film 202 is coated by magnetron sputtering coating method, and the film structure is SUB (substrate)/N _M 22nm/N _L 27nm/N _H 109nm/N _L 86nm/AIR (air) , the total thickness of the film layer is 0.244μ, where N _H , N _M , and N _L are high, medium, and low refractive index dielectric materials with a refractive index of 2.15-2.35, 1.85-2.05, and 1.35-1.46, respectively. Preferably, N _H , N _M , and N _L are high, medium, and low refractive index dielectric materials with a refractive index of 2.35, 2.05, and 1.46 for the sputtered film material, respectively, achieving an average reflectance of less than 0.5% in the visible light spectrum range , The broadband anti-reflection effect with an average transmittance greater than 99.5%, effectively reduces the reflected stray light on the outer surface of the optical lens 200 and the overall light transmittance, and improves the imaging quality of the near-eye display. The spectral characteristic curve is shown in Figure 3.

There are many types of high, medium and low refractive index dielectric materials that can be selected for the above-mentioned optical films and are easy to obtain. For example, the above-mentioned functional optical films composed of TiO2, Al2O3, SiO2, etc. have strong scratch resistance and good environmental resistance. Features, no special protection can be used for a long life;

Therefore, the optical lens 200 of the present invention not only has the function of narrow-band spectral reflection imaging, but also has good transparency and vision correction functions. It has a lens that replaces the prior art and requires multiple or multi-layer glued structures or other complex surface morphology structures. functions that can be realized. The above-mentioned image projection unit 100 is installed on the side of the optical lens 200, and the output image light can be directly projected to the inner surface of the optical lens 200, reflected by the optical film 201 to the retina of the human eye for imaging, and forms an enlarged virtual image in front of the human eye to achieve near-eye display purpose, as shown in Figure 1.

The above display describes the basic principle, main features and advantages of the invention. Those skilled in the art should understand that the present invention is not limited by the above-mentioned embodiments, and those described in the above-mentioned embodiments and description are only preferred examples of the present invention, and are not intended to limit the present invention, without departing from the spirit and scope of the present invention. Under the premise, the present invention will have various changes and improvements, and these changes and improvements all fall within the scope of the claimed invention. The protection scope of the present invention is defined by the appended claims and their equivalents.

Claims

A reflection spectrum imaging system for near-eye display, characterized in that: it is composed of an image projection unit (100) and an optical lens (200) having an optical film reflection spectrum imaging function; the image projection unit (100) is Red (λ R ±δ λR )/green (λ G ±δ λG )/blue (λ B ±δ λB )/or more monochromatic like yellow (λ Y ±δ λY ) LEDs, lasers containing narrow-band spectral features , OLED lighting, display, imaging optical projection system, or an image optical projection system that does not have the narrow-band spectral characteristics of monochromatic light source lighting, display, and imaging, but is added with a narrow-band filter method to produce the same effect; the optical lens ( The inner surface of 200) has an optical surface matching the image projection unit (100) and is provided with an optical film (201) with reflective spectrum imaging function; Or astigmatism vision correction function optical surface and equipped with broadband anti-reflection optical anti-reflection film (202) in the range of visible light spectrum, optical film (201) is in the range of visible light spectrum 400nm-760nm, with image projection unit ( 100) output red (λ R ± δ λR ) / green (λ G ± δ λG ) / blue (λ B ± δ λB ) / or more monochromatic such as yellow (λ Y ± δ λY ) to match the characteristic spectrum The narrow-band spectrum has high reflection characteristics, and has the characteristics of high transmission to the rest of the spectrum; the optical anti-reflection coating (202) can improve the overall light transmittance of the optical lens, effectively eliminate the interference of stray light reflected from the outer surface of the optical lens, and improve the imaging of near-eye display quality; the above-mentioned image projection unit (100) is installed on the side of the optical lens (200), and the output image light can be directly projected to the inner surface of the optical lens (200), reflected by the optical film (201) to the retina of the human eye for imaging and human A magnified virtual image is formed in front of the eye to achieve near-eye display.
The reflection spectrum imaging system for near-eye display according to claim 1, characterized in that: the optical lens (200) is made of optical glass or optical plastic transparent material through grinding and polishing or molding or injection molding, and the optical film (201), the optical anti-reflection film (202) is plated by optical coating technology.
The reflection spectrum imaging system for near-eye display according to claim 1, characterized in that: when the light output by the image projection unit (100) is polarized light, the red (λ R ± The narrow-band spectral reflection properties of δ λR )/green (λ G ±δ λG )/blue (λ B ±δ λB )/or more monochromatic like yellow (λ Y ±δ λY ) are designed for the corresponding polarization state.
The reflection spectrum imaging system for near-eye display according to claim 1, characterized in that: the optical lens (200) is made of the optical film (201) and a material with photochromic or electrochromic function or with Composed of a combination of color filter lenses with reduced light transmittance, the optical lens (200) can improve the contrast and clarity of imaging display used outdoors or in strong light environments.
The reflection spectrum imaging system for near-eye display according to claim 1, characterized in that: the optical film (201) can be plated on other transparent film substrates and then pasted on the inner surface of the optical lens (200) or Glued between two lenses as a sandwich.
The reflection spectrum imaging system for near-eye display according to claim 1, characterized in that: the film structure of the optical film (201) is composed of SUB (substrate)/N M 92nm/N L 64nm/N M 50nm /N L 20nm/N H 18nm/N L 184nm/N H 112nm/N L 42nm/N H 19nm/N L 30nm/N H 139nm/N L 38nm/N H 106nm/ N L 27nm/N H 107nm/N L 56nm/N H 23nm/N M 44nm/N H 89nm/N M 187nm/N H 66nm/N M 151nm/N H 32nm/N M 34nm/N H 86nm/N L 134nm/N M 78nm/ N H 40nm /N M 113nm/N L 12nm/N M 170nm/N L 48nm/N M 28nm/N L 39nm/N H 83nm/N L 36nm/N H 112nm/N L 22nm/ N H 23nm /N M 48nm/N Composition of H 105nm/N M 150nm/N H 81nm/N M 39nm/AIR (air), where N H , N M , N L , respectively, have refractive indices in the range of 2.00-2.55, 1.60-1.85, 1.35-1.48 For high, medium and low refractive index dielectric materials, the thickness of each layer of the above-mentioned film structure can be adjusted within the range of ±10%.
The reflection spectrum imaging system for near-eye display according to claim 1, characterized in that: the film structure of the optical anti-reflection coating (202) is SUB (substrate)/N M 22nm/N L 27nm/N H Composition of 109nm/N L 86nm/AIR (air), in which N H , N M , N L are high, medium and low refractive index dielectric materials with a refractive index of 2.15-2.35, 1.85-2.05, 1.35-1.46, respectively.