Three-dimensional (3D) electronic displays provide different 3D views and employ one or both of an array of multibeam diffraction gratings arranged in offset rows and light valves having color filters. The displays include a plate light guide configured to guide light beams at a non-zero propagation angle, a multibeam diffraction grating configured to couple out a portion of the guided light beams as a plurality of light beams having different principal angular directions representing the different 3D views, and light valves configured to modulate the differently directed, coupled-out light beams. The multibeam diffraction grating may be a member of the array arranged in offset rows and the display may further include light valves having color filters. Alternately, the light valves include color filters and the display may further include the array of multibeam diffraction gratings arranged in offset rows.

A device includes a waveguide. The device also includes a plurality of grating sets coupled with the waveguide and configured to, during a plurality of time periods, couple a plurality of input image lights into and out of the waveguide as a plurality of output image lights. In a first grating set of the plurality of grating sets, a first vector sum of in-plane projections of grating vectors associated with all gratings included in the first grating set is a first non-null vector. In a second grating set of the plurality of grating sets, a second vector sum of in-plane projections of grating vectors associated with all gratings included in the second grating set is a second non-null vector. The first vector sum and the second vector sum have different directions.

An optical waveguide comprises at least two TIR surface and contains a grating. Input TIR light with a first angular range along a first propagation direction undergoes at least two diffractions at the grating. Each diffraction directs light into a unique TIR angular range along a second propagation direction.

A biosensor is provided. The biosensor includes a plurality of sensor units. Each of the sensor units includes one or more photodiodes, a first aperture feature disposed above the photodiodes, an interlayer disposed on the first aperture feature, a second aperture feature disposed on the interlayer, and a waveguide disposed above the second aperture feature. The second aperture feature includes an upper grating element and the first aperture feature includes one or more lower grating elements, and a grating period of the upper grating element is less than or equal to a grating period of the one or more lower grating elements. A difference of the absolute values between a first polarizing angle of the upper and lower grating elements in one of the sensor units and a second polarizing angle of the upper and lower grating elements in adjacent one of the sensor units is 90°.

An image light guide for conveying a virtual image, including a waveguide, an in-coupling diffractive optic operable to direct image-bearing light beams into the waveguide, and an out-coupling diffractive optic operable to direct the image-bearing light beams from the waveguide toward an eyebox. The out-coupling diffractive optic having two or more zones each including a set of diffractive features, wherein successive zones along one dimension of the out-coupling diffractive optic have different respective sets of diffractive features, wherein the diffractive features are operable to direct image-bearing light beams of a first pixel incident upon the diffractive features at a first angle whereby the directed image-bearing light beams of the first pixel further propagate within the waveguide, and wherein the diffractive features are operable to out-couple a portion of the image-bearing light beams of the first pixel incident upon the diffractive features at a second angle.

An optical display system and an augmented reality electronic device are disclosed. The optical display system comprises: a waveguide; an input coupler, provided at the input end of the waveguide and couples an image light into it; and a two-dimensional grating, provided at the output end of waveguide. The waveguide delivers the image light to the two-dimensional grating, which performs pupil expansion on the image light and out-couples the expanded image light. The two-dimensional grating has rhombus lattices. Unit cells of the two-dimensional grating are un-symmetric along respective axes parallel with a propagation direction of the image light incident onto the two-dimensional grating, from a top view of the two-dimensional grating. The unit cells are oriented with the propagation direction of the image light and each of the unit cells has at least two vertexes at its end side.

Technologies for silicon diffraction gratings are disclosed. In some embodiments, grating lines of the diffraction gratings may have several sub-lines that make up each grating line of the diffraction grating. The sub-lines may be sub-wavelength features. In some embodiments, several silicon diffraction gratings may be made from a wafer, such as a wafer with a diameter of 300 millimeters. The wafer may be etched precisely across the entire wafer, leading to a high yield of the diffraction gratings.

A biosensor is provided. The biosensor includes a plurality of sensor units. Each of the sensor units includes one or more photodiodes, a first aperture feature disposed above the photodiodes, an interlayer disposed on the first aperture feature, a second aperture feature disposed on the interlayer, and a waveguide disposed above the second aperture feature. The second aperture feature includes an upper grating element and the first aperture feature includes one or more lower grating elements, and a grating period of the upper grating element is less than or equal to a grating period of the one or more lower grating elements. A difference of the absolute values between a first polarizing angle of the upper and lower grating elements in one of the sensor units and a second polarizing angle of the upper and lower grating elements in adjacent one of the sensor units is 90°.

A design method of a diffractive optical assembly, and a diffractive optical assembly. The design method comprises: S110, designing a first diffractive optical element according to a target light field; S120, simulating the first diffractive optical element to obtain a first light field difference between the simulation light field of the first diffractive optical element and the target light field; and S130, designing a second diffractive optical element according to the first light field difference. According to the design method, the performance of the diffractive optical assembly can be improved.

The invention relates to image display technology, in particular to a device for rendering an augmented reality image and a system for realizing augmented reality display comprising the device. The device according to one aspect of the invention comprises: an optical waveguide lens; and a first two-dimensional grating array located on a surface of the optical waveguide lens; a second two-dimensional grating array located on the surface of the optical waveguide lens, wherein, positions of the first two-dimensional grating array and the second two-dimensional grating array on the surface of the optical waveguide lens are set so that larger edges of the two are opposite, wherein, the first two-dimensional grating array is configured such that rays incident on the first two-dimensional grating array expands to the entire first two-dimensional grating array on the one hand, and propagates to the second two-dimensional grating array on the other hand, wherein, the second two-dimensional grating array is configured such that rays propagating to the second two-dimensional grating array expands to the entire second two-dimensional grating array on the one hand, and emits from the optical waveguide lens on the other hand, wherein, the first two-dimensional grating array and the second two-dimensional grating array have the same period.