CN214335368U - Optical system and mixed reality equipment - Google Patents

Abstract

The utility model discloses an optical system and mixed reality equipment. The optical system includes: a projection device for projecting two beams of image light; a base layer having two sides for receiving the two image lights from the projection device, respectively, and two planes for totally reflecting the two image lights entering the base layer; and the diffraction grating layer is at least arranged on one plane of the substrate layer and is used for reflecting, diffracting or transmitting and diffracting the two beams of image light transmitted in the substrate layer, wherein the energy of the target image light diffracted by the diffraction grating layer is uniformly distributed. The utility model discloses optical system and mixed reality equipment can provide compacter structure, provides better sense of immersing.

Description

Optical system and mixed reality equipment

Technical Field

The utility model belongs to the technical field of photoelectron, in particular to optical system and mixed reality equipment.

Background

The mixed reality equipment comprises virtual reality equipment and augmented reality equipment, the virtual reality equipment only presents virtual image information for a user, and external environment light cannot enter the eyes of the user through the virtual reality equipment, and the augmented reality equipment can present the virtual image information and the external environment light to the eyes of the user simultaneously.

Optical waveguide technology, as one of optical systems in mixed reality equipment, has gained increasing heat due to its thinness and high penetration of external light.

SUMMERY OF THE UTILITY MODEL

Embodiments of the present application first provide an optical system including: a projection device for projecting two beams of image light; a base layer having two sides for receiving the two image lights from the projection device, respectively, and two planes for totally reflecting the two image lights entering the base layer; and the diffraction grating layer is at least arranged on one plane of the substrate layer and is used for reflecting, diffracting or transmitting and diffracting the two beams of image light transmitted in the substrate layer, wherein the energy of the target image light diffracted by the diffraction grating layer is uniformly distributed.

In some embodiments, when the diffraction grating layer is disposed on one plane of the base layer, the diffraction grating layer is distributed in axial symmetry with respect to grating stripes in a direction perpendicular to the diffraction grating layer from preset position points, which are located on the diffraction grating layer.

In some embodiments, in the case of transmission-diffracting out by the diffraction grating layer, in a direction from an edge of the diffraction grating layer to the preset position point of the image light transmitted in the base layer, the transmission-diffraction efficiency of the image light gradually increases; in a direction from the preset position point to the other edge of the diffraction grating layer, the reflection diffraction efficiency of the image light transmitted in the substrate layer gradually decreases.

In some embodiments, the transmission diffraction efficiency of the image light and the reflection diffraction efficiency of the image light are axisymmetric with respect to a direction perpendicular to the diffraction grating layer from the predetermined position point.

In some embodiments, in a direction from the edge of the diffraction grating layer to the preset position point, the transmitted and diffracted light intensity value of the image light transmitted in the base layer is a constant value; and in the direction from the preset position point to the other edge of the diffraction grating layer, the reflected and diffracted light intensity value of the image light transmitted in the substrate layer is smaller than the transmitted and diffracted light intensity value.

In some embodiments, the reflected and diffracted light intensity value of the image light transmitted in the substrate layer gradually decreases in a direction from the preset position point to the other edge of the diffraction grating layer.

In some embodiments, the optical system further comprises: and the two coupling prisms are respectively arranged on two side surfaces of the substrate layer and are respectively used for coupling the two beams of image light from the projection device into the substrate layer through the two side surfaces.

In some embodiments, the optical system further comprises: and the two reflecting elements are respectively arranged on the light paths of the two beams of image light of the projection device, which correspondingly enter the coupling prism, and are used for respectively reflecting the two beams of image light from the projection device to the corresponding coupling prism.

In some embodiments, the optical system further comprises: and the transflective element is arranged on a light path from the target image light diffracted by the diffraction grating layer to human eyes, is used for reflecting the target image light diffracted by the diffraction grating layer into the human eyes, and is used for allowing ambient light to be transmitted into the human eyes through the transflective element.

The embodiment of the application also discloses mixed reality equipment which comprises a data processing module and the optical system, wherein the data processing module transmits image information to be displayed to a projection device of the optical system so as to display an image.

By arranging the projection device, the substrate layer and the diffraction grating layer, the energy of the target image light emitted by the optical system is uniformly distributed, the optical system is more compact, the target image light emitted by the optical system can respectively correspond to two eyes of a user, two different optical systems do not need to be arranged for each eye of the user, and the immersion feeling of the mixed reality equipment using the optical system is better.

The objects, and features of the invention will be set forth in part in the description which follows, and in part will become apparent to those skilled in the art upon examination of the following or may be learned from practice of the invention. The objectives and other advantages of the invention will be realized and attained by the structure particularly pointed out in the written description and claims hereof as well as the appended drawings.

Drawings

The accompanying drawings are included to provide a further understanding of the technology or prior art of the present application and are incorporated in and constitute a part of this specification. The drawings expressing the embodiments of the present application are used for explaining the technical solutions of the present application, and should not be construed as limiting the technical solutions of the present application.

Fig. 1 is a schematic structural diagram of an optical system according to an embodiment of the present invention;

fig. 2 is a schematic structural diagram of an optical system according to another embodiment of the present invention;

FIG. 3 is another angled view of FIG. 2;

fig. 4 is a schematic structural diagram of a base layer and a diffraction grating layer in an optical system according to an embodiment of the present invention;

fig. 5 is a graph of diffraction efficiency of image light in an optical system according to an embodiment of the present invention;

fig. 6 is a graph of the absolute intensity of diffraction of image light in an optical system according to an embodiment of the present invention;

fig. 7 is a schematic structural diagram of a mixed reality device according to an embodiment of the present invention.

Detailed Description

The following describes embodiments of the present invention in detail with reference to the accompanying drawings and examples, so that how to apply the technical means to solve the technical problems of the present invention and achieve the corresponding technical effects can be fully understood and implemented. Each characteristic in this application embodiment and the embodiment can combine each other under the prerequisite of not conflicting, and the technical scheme who forms is all in the utility model discloses a within the scope of protection.

Referring to fig. 1, an optical system 100 is disclosed in the present embodiment, which includes projection devices 101 and 102, a substrate layer 400, and a diffraction grating layer.

And the projection device is used for projecting two beams of image light. One projection device may transmit two image lights, for example, by splitting the light projected by one projection device into two image lights. In the manner shown in fig. 1, the two projection devices 101 and 102 each emit a beam of image light. The two projection devices 101,102 may be symmetrically positioned with respect to a perpendicular to the center positions of the two planes of the substrate layer 400.

A substrate layer 400 having two sides for receiving the two image lights originating from the projection means 101,102, respectively, and two planes for total reflection of the two image lights entering the substrate layer 400. Referring to fig. 1, the substrate layer 400 may be, for example, a trapezoid, and two sides of the trapezoid are respectively used for receiving two image lights, and the two image lights are respectively propagated in two opposite planes by total reflection. Specifically, a beam of image light enters substrate layer 400 through one side and propagates in total reflection in two opposing planes of substrate layer 400 toward the other side.

Diffraction grating layers 501 and 502, which are disposed on at least one plane of the substrate layer 400, are used to reflect, diffract or transmit and diffract the two image lights propagating in the substrate layer 400. Wherein the energy of the object image light 1000 diffracted out by the diffraction grating layers 501,502 is uniformly distributed. Both image lights can exit through the optical system 100, and the effect of pupil continuity can be achieved. When image light propagates in the substrate layer 400, it exits in a reflective or transmissive diffractive manner when it encounters a flat surface disposed on the substrate layer 400, and the exiting image light is referred to as target image light 1000. For example, the diffraction grating layer is divided into two layers, one layer is disposed on the lower plane of the substrate layer 400, and the other layer is disposed on the upper plane of the substrate layer 400, wherein the image light corresponding to one layer is emitted in a reflection diffraction manner, and the image light corresponding to the other layer is emitted in a transmission diffraction manner. For another example, referring to fig. 1, the diffraction grating layers 501 and 502 are one layer, one diffraction grating layer 501 and 502 is attached to one plane of the base layer 400, and the image light is emitted in a transmission diffraction manner, and when the image light encounters the diffraction grating layer, the image light is emitted in a transmission diffraction manner, and the energy of the emitted target image light 1000 is uniformly distributed. In fig. 1, the left portion of the diffraction grating layer is denoted by 502, and the right portion of the diffraction grating layer is denoted by 501, which are actually an integral diffraction grating layer, and the energy of the emitted target image light 1000 is uniformly distributed on the diffraction grating layer, that is, the energy of the emitted target image light 1000 corresponding to different positions of the diffraction grating layer is equal. The center positions of the diffraction grating layers 501,502 may coincide with the center position of the substrate layer 400.

By providing the projection devices 101 and 102, the base layer 400 and the diffraction grating layers 501 and 502, the energy of the target image light 1000 emitted by the optical system 100 is uniformly distributed, the optical system 100 is more compact, the target image light 1000 emitted by the optical system 100 can respectively correspond to two eyes of a user, two different optical systems do not need to be respectively arranged for each eye of the user, and the immersion feeling of a mixed reality device using the optical system 100 is better.

In some embodiments, the projection device 101,102 may specifically include a projection lens and a display screen, the display screen is used for loading the image information to be displayed and further emitting the image information to be displayed to the projection lens in the form of light, and the projection lens may be used for collimating and transmitting the image information in the form of light (image light) to the downstream of the optical path. The projection devices 101,102 may be attached to both sides of the substrate layer 400.

In some embodiments, referring to fig. 1, the optical system 100 may further include two coupling prisms 301,302 respectively disposed on two sides of the substrate layer 400 for respectively coupling the two image lights originating from the projection devices 101,102 into the substrate layer 400 through the two sides. The image light emitted from the projection device 101 may be incident on the substrate layer 400 through one side of the substrate layer 400 via the coupling prism 301, and the image light emitted from the projection device 102 may be incident on the substrate layer 400 through the other side of the substrate layer 400 via the coupling prism 302. Wherein the two coupling prisms 301,302 can be glued on the two sides of the substrate layer 400, and the projection devices 101,102 are attached to the two coupling prisms 301,302, respectively. The two projection devices 101 and 102 may be symmetrically disposed with respect to a perpendicular line to the center positions of the two planes of the substrate layer 400, and the two coupling prisms 301 and 302 may be symmetrically disposed with respect to a perpendicular line to the center positions of the two planes of the substrate layer 400.

In some embodiments, the optical system 100 may further include two reflective elements 201,202, which are respectively disposed on the optical paths of the two image lights of the projection devices 101,102 incident to the coupling prisms 301,302, respectively, and are used for reflecting the two image lights from the projection devices 101,102 to the corresponding coupling prisms 301,302, respectively. The image light emitted from the projection devices 101 and 102 is reflected by the reflection elements 201 and 202 and enters the coupling prisms 301 and 302, and the coupling prisms 301 and 302 couple the image light into the substrate layer 400. Wherein, two coupling prisms 301,302 can be respectively attached on two sides of the substrate layer 400, and the projection devices 101,102 can be disposed parallel to the plane of the substrate layer 400. If the projection devices 101 and 102 are disposed near the edge of the substrate layer 400 or outside the substrate layer 400, the effect that ambient light is incident on human eyes through the substrate layer 400 and the diffraction grating layers 501 and 502 is not affected, and the optical system 100 can achieve the effect that both image light and external ambient light are incident on human eyes. The substrate layer 400 and the diffraction grating layers 501 and 502 may be made of, for example, optical glass or optical plastic of a transparent material. The high transmittance of the substrate layer 400 and the diffraction grating layers 501,502 may reduce absorption of light by the substrate layer 400 and the diffraction grating layers 501, 502. Referring to fig. 1, if the projection devices 101 and 102 are disposed near the center of the substrate layer 400, which may affect the ambient light to be incident on the human eye through the substrate layer 400 and the diffraction grating layers 501 and 502, the optical system 100 can only achieve the effect of the image light to be incident on the human eye. The two reflecting elements 201,202 are angled with respect to the two projection means 101,102 and the two coupling prisms 301,302, respectively, to reflect the image light rays exiting the projection means 101,102 into the coupling prisms 301, 302. The two projection devices 101,102 may be symmetrically disposed with respect to a perpendicular to the center positions of the two planes of the substrate layer 400, the two coupling prisms 301,302 may be symmetrically disposed with respect to a perpendicular to the center positions of the two planes of the substrate layer 400, and the two reflective elements 201,202 may be symmetrically disposed with respect to a perpendicular to the center positions of the two planes of the substrate layer 400. The two projection devices 101,102, the two reflecting elements 201,202, the two coupling prisms 301,302 share a common base layer 400 and diffraction grating layers 501,502, and the optical system 100 is more compact and less bulky.

In some embodiments, referring to fig. 2 and 3, the optical system 200 may further include: the transflective element 600 is disposed on an optical path from the target image light 1000 diffracted by the diffraction grating layers 501 and 502 to the human eye 700, and is used for reflecting the target image light 1000 diffracted by the diffraction grating layers 501 and 502 into the human eye and transmitting ambient light into the human eye 700 through the transflective element 600. When the optical system 100 can only achieve the effect of the image light entering human eyes, the transflective element 600 may be added on the basis of the optical system 100, the target image light 1000 emitted from the optical system 100 is reflected by the transflective element 600 to obtain the image light 1001, the image light 1001 may enter the human eyes 700, and the ambient light may enter the human eyes 700 through the transflective element 600. The optical system 200 may achieve an effect that both image light and external environment light are incident to the human eye 700. The human eye 700 has a rectangular exit pupil.

In the above optical system, referring to fig. 4, when diffraction grating layers 501,502 are provided on one plane of the base layer 400, for example, on the upper surface of the base layer 400, the diffraction grating layers 501,502 (which are one layer diffraction grating layer as a whole) are distributed in axial symmetry with respect to grating stripes in a direction (Z axis shown in fig. 4) perpendicular to the diffraction grating layers 501,502 at preset position points (0 point shown in fig. 4) on the diffraction grating layers 501, 502. The X-axis in fig. 4 is located between the substrate layer 400 and the diffraction grating layers 501 and 502, the 0 point is located at the center of the diffraction grating layers 501 and 502 (the 0 point is located at the boundary between the portion of the diffraction grating layer 501 and the portion of the diffraction grating layer 502), and the Z-axis is the 0 point in the direction perpendicular to the diffraction grating layers 501 and 502. The diffraction grating layers 501 and 502 may be holographic gratings or surface relief gratings, among others.

Referring to fig. 5, in the case of transmission-diffracted out through the diffraction grating layers 501 and 502, the transmission-diffraction efficiency of the image light gradually increases in the direction from the edges of the diffraction grating layers 501 and 502 to the preset position points of the image light transmitted in the base layer 400; in the direction from the preset position point to the other edge of the diffraction grating layers 501,502 of the image light transmitted in the base layer 400, the reflection diffraction efficiency of the image light gradually decreases. Incident light 1 (the light of which-1 order of transmission diffraction and reflection diffraction are both perpendicular to the plane surface of the base layer 400) shown in fig. 4 propagates in the direction from the diffraction grating layer 502 portion to the diffraction grating layer 501 portion, and the distribution of the transmission diffraction efficiency T of the diffraction grating layer 502 portion and the reflection diffraction efficiency R of the diffraction grating layer 501 portion in fig. 5 shows that the diffraction efficiency is highest at point 0, and the farther from point 0, the lower the diffraction efficiency, and the transmission diffraction efficiency T of the diffraction grating layer 502 portion and the reflection diffraction efficiency R of the diffraction grating layer 501 portion gradually increase from the edge to point 0. The diffraction efficiency may also be increased in steps, for example, from the edge to the 0 point, the transmission diffraction efficiency T of the diffraction grating layer 502 portion and the reflection diffraction efficiency R of the diffraction grating layer 501 portion are increased in steps. Incident ray 2 shown in fig. 4 travels in a direction from a portion of the diffraction grating layer 501 to a portion of the diffraction grating layer 502, which is similar to incident ray 1 and will not be described again.

In some embodiments, the transmission diffraction efficiency of the image light and the reflection diffraction efficiency of the image light are axisymmetric with respect to a direction perpendicular to the diffraction grating layers 501,502 from a point at a predetermined position. As can be seen from fig. 5, the transmission diffraction efficiency T of the diffraction grating layer 502 portion and the reflection diffraction efficiency R of the diffraction grating layer 501 portion are symmetrically distributed with respect to the Z axis. Of course, in some cases, the transmission diffraction efficiency T of the diffraction grating layer 502 portion and the reflection diffraction efficiency R of the diffraction grating layer 501 portion may also be asymmetrically distributed with respect to the Z-axis. The transmission diffraction efficiency T of the diffraction grating layer 502 portion and the reflection diffraction efficiency R of the diffraction grating layer 501 portion may gradually increase from the edge to the 0 point, but the increasing curves may be different.

Referring to fig. 6, in a direction from the edges of the diffraction grating layers 501 and 502 to the preset position points of the image light transmitted in the substrate layer 400, the transmitted and diffracted light intensity value of the image light is a constant value; in the direction from the predetermined position point to the other edge of the diffraction grating layers 501 and 502, the image light transmitted in the base layer 400 has a smaller reflected diffraction intensity value than a transmitted diffraction intensity value. Fig. 6 shows the distribution of the diffraction absolute light intensity of the incident light 1 at the diffraction grating layer 502 portion and the diffraction grating layer 501 portion, that is, the distribution of the diffraction absolute light intensity values at the diffraction grating layer 502 portion and the diffraction grating layer 501 portion. The diffraction grating layer 502 portion has nearly flat transmitted energy t, i.e., a constant value of transmitted diffracted light intensity. Similarly, when the incident light ray 2 travels from the portion of the diffraction grating layer 501 toward the portion of the diffraction grating layer 502, the incident light ray 2 also has a constant value of transmitted diffracted light intensity at the portion of the diffraction grating layer 501. When the incident light 1 travels from the portion of the diffraction grating layer 502 toward the diffraction grating layer 501, the incident light 1 is extracted by the diffraction grating layer 502 a plurality of times of transmitted diffraction energy, the remaining light energy when traveling to the portion of the diffraction grating layer 501 is very weak, and the transmitted diffraction efficiency of the portion of the diffraction grating layer 501 for the incident light 1 is 1-R, the transmitted diffraction of the portion of the diffraction grating layer 501 for the incident light 1 is insignificant, and similarly, the transmitted diffraction of the portion of the diffraction grating layer 502 for the incident light 2 is also insignificant, and the entire area of the diffraction grating layers 501,502 has a uniform transmitted diffraction energy distribution.

In some embodiments, the reflected and diffracted light intensity values of the image light gradually decrease in the direction from the predetermined location point to the other edge of the diffraction grating layers 501,502 where the image light is transmitted in the substrate layer 400. The smaller the reflected and diffracted light intensity value of the image light, the better the transmission diffraction effect on the diffraction grating layers 501, 502.

The manufacturing process of the diffraction grating layers 501,502 may be to adjust the exposure time at different positions by holographic exposure to obtain the required diffraction efficiency.

Referring to fig. 7, the present application also provides a mixed reality apparatus including the optical system 100,200 described above and a data processing module that transmits image information to be displayed to the projection device 101,102 of the optical system 100,200 to display an image. The data processing module in the mixed reality device is used for providing image information to be displayed and transmitting the image information to the projection devices 101 and 102 for the optical systems 100 and 200 to conduct to human eyes. When the mixed reality equipment is used as virtual reality equipment, only image information is displayed, and when the mixed reality equipment is used as augmented reality equipment, the image information and the external environment information are displayed. The mixed reality device may be, for example, a glasses type device including a glasses frame 300 and the optical system 100 connected to the glasses frame 300, and the data processing module may be disposed in the glasses frame 300. The optical system 100 can provide a full-view lens sheet with an integral structure, so that when a user wears the glasses, the bridge of the nose is not shielded, and the light and thin structure, the simpler structure and the higher immersive visual experience of the augmented reality glasses can be provided. Wherein, the diffraction grating layer 501 part can provide images for the left eye, the diffraction grating layer 502 part provides images for the right eye, the diffraction grating layer 501 part and the diffraction grating layer 502 part are both corresponding to the substrate layer 400, and the substrate layer 400 can be a transparent waveguide. The entire optical system 100 is filled with virtual images and can provide a larger eyebox than current augmented reality glasses.

The above description is only a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present invention should be covered by the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (10)

1. An optical system, comprising:

a projection device for projecting two beams of image light;

a base layer having two sides for receiving the two image lights from the projection device, respectively, and two planes for totally reflecting the two image lights entering the base layer; and

and the diffraction grating layer is at least arranged on one plane of the substrate layer and is used for reflecting, diffracting or transmitting and diffracting the two beams of image light transmitted in the substrate layer, wherein the energy of the target image light diffracted by the diffraction grating layer is uniformly distributed.

2. The optical system according to claim 1, wherein when the diffraction grating layer is disposed on one plane of the base layer, the diffraction grating layer is axisymmetrically distributed with respect to grating stripes in a direction perpendicular to the diffraction grating layer from preset position points on the diffraction grating layer.

3. The optical system according to claim 2, wherein in a case where the image light transmitted in the base layer is transmission-diffracted out through the diffraction grating layer, a transmission diffraction efficiency of the image light is gradually increased in a direction from an edge of the diffraction grating layer to the preset position point; in a direction from the preset position point to the other edge of the diffraction grating layer, the reflection diffraction efficiency of the image light transmitted in the substrate layer gradually decreases.

4. The optical system according to claim 3, wherein the transmission diffraction efficiency of the image light and the reflection diffraction efficiency of the image light are axisymmetric with respect to a direction perpendicular to the diffraction grating layer from the predetermined position point.

5. The optical system according to claim 3, wherein a transmitted diffracted light intensity value of the image light transmitted in the substrate layer is a constant value in a direction from an edge of the diffraction grating layer to the predetermined position point; and in the direction from the preset position point to the other edge of the diffraction grating layer, the reflected and diffracted light intensity value of the image light transmitted in the substrate layer is smaller than the transmitted and diffracted light intensity value.

6. The optical system as claimed in claim 5, wherein the image light transmitted in the substrate layer gradually decreases in intensity value of reflected and diffracted light in a direction from the predetermined position point to the other edge of the diffraction grating layer.

7. The optical system of claim 1, further comprising:

and the two coupling prisms are respectively arranged on two side surfaces of the substrate layer and are respectively used for coupling the two beams of image light from the projection device into the substrate layer through the two side surfaces.

8. The optical system of claim 7, further comprising:

and the two reflecting elements are respectively arranged on the light paths of the two beams of image light of the projection device, which correspondingly enter the coupling prism, and are used for respectively reflecting the two beams of image light from the projection device to the corresponding coupling prism.

9. The optical system of claim 8, further comprising:

and the transflective element is arranged on a light path from the target image light diffracted by the diffraction grating layer to human eyes, is used for reflecting the target image light diffracted by the diffraction grating layer into the human eyes, and is used for allowing ambient light to be transmitted into the human eyes through the transflective element.

10. A mixed reality device comprising a data processing module and the optical system of any one of claims 1 to 9, the data processing module transmitting image information to be displayed to a projection device of the optical system to display an image.

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