Abstract: This application provides an image display method and an image display apparatus, and is beneficial to improving uniformity of an image displayed by using a diffractive waveguide, thereby improving user experience. The method is applied to an apparatus including an optical engine and the diffractive waveguide and includes: obtaining uniformity data of a first image obtained by using the diffractive waveguide; determining to-be-compensated data of the optical engine based on the uniformity data; adjusting luminance distribution of a light source in the optical engine based on the to-be-compensated data; and displaying a second image by using the adjusted optical engine and the diffractive waveguide.

Abstract: This application provides an image display method and an image display apparatus, and is beneficial to improving uniformity of an image displayed by using a diffractive waveguide, thereby improving user experience. The method is applied to an apparatus including an optical engine and the diffractive waveguide and includes: obtaining uniformity data of a first image obtained by using the diffractive waveguide; determining to-be-compensated data of the optical engine based on the uniformity data; adjusting luminance distribution of a light source in the optical engine based on the to-be-compensated data; and displaying a second image by using the adjusted optical engine and the diffractive waveguide.

Abstract: A tap photodetector includes at least one detection unit configured to detect an optical signal. Each detection unit may separately detect an optical signal. Each detection unit includes a transparent zone and a detection zone. The transparent zone is configured to transmit a part of an optical signal, and the detection zone is disposed on a periphery of the transparent zone and is configured to detect another part of the optical signal that does not pass through the transparent zone.

Abstract: A radar is provided. The radar includes a light source, a first beam diffraction element, a second beam diffraction element, a reflection assembly, and a detector. The first beam diffraction element is configured to diffract a ray emitted by the light source into at least two first beams (a, b, c). The second beam diffraction element is configured to converge the at least two first beams (a, b, c) to a specified position. Then, the at least two first beams are reflected to a detection area by the reflection assembly. The reflection assembly includes a reflector configured to reflect the at least two first beams (a, b, c) converged to the specified position to a detection area, and a driving mechanism configured to drive the reflector to swing. The detector is configured to receive at least two second beams (a?, b?, c?) reflected back from the detection area.

Abstract: An augmented reality (AR) apparatus and method, and an optical engine component, where the AR apparatus includes a light-emitting light source, a polarization splitting subsystem, a first image source, a first optical subsystem, and a first combination subsystem. The first optical subsystem includes a first lens group, a first quarter-wave plate, and a first reflection surface. The first optical subsystem is configured to receive second polarized light and output first polarized light to the first combination subsystem. The first combination subsystem is configured to combine the received first polarized light and received external ambient light, and combined light is projected into an eye.

Abstract: An augmented reality (AR) apparatus and method, and an optical engine component, where the AR apparatus includes a light-emitting light source, a polarization splitting subsystem, a first image source, a first optical subsystem, and a first combination subsystem. The first optical subsystem includes a first lens group, a first quarter-wave plate, and a first reflection surface. The first optical subsystem is configured to receive second polarized light and output first polarized light to the first combination subsystem. The first combination subsystem is configured to combine the received first polarized light and received external ambient light, and combined light is projected into an eye.

Abstract: An optical waveguide detector is provided, which includes: a silicon waveguide layer and a germanium waveguide layer. The germanium waveguide layer includes a first heavily germanium-doped area and a germanium-undoped area. A first surface of the germanium waveguide layer includes a surface of the first heavily germanium-doped area, and the first surface is a surface of the germanium waveguide layer away from the silicon waveguide layer in the first direction. A width of the first heavily germanium-doped area is less than or equal to half a width of the first surface, and a thickness of the first heavily germanium-doped area is greater than or equal to 5 nm and less than or equal to 200 nm. According to embodiments, a bandwidth of the optical waveguide detector can be effectively increased.

Abstract: An optical waveguide detector is provided, which includes: a silicon waveguide layer and a germanium waveguide layer. The germanium waveguide layer includes a first heavily germanium-doped area and a germanium-undoped area. A first surface of the germanium waveguide layer includes a surface of the first heavily germanium-doped area, and the first surface is a surface of the germanium waveguide layer away from the silicon waveguide layer in the first direction. A width of the first heavily germanium-doped area is less than or equal to half a width of the first surface, and a thickness of the first heavily germanium-doped area is greater than or equal to 5 nm and less than or equal to 200 nm. According to embodiments, a bandwidth of the optical waveguide detector can be effectively increased.