The present disclosure provides an imaging optical system. In one aspect, the imaging optical system includes, among other things, a light bending element configured to substantially separate electromagnetic radiation into at least two portions, and configured to redirect the at least two portions of said electromagnetic radiation into substantially different directions.

An invisible laser system and an optical path visualization method thereof are disclosed. The invisible laser system comprises an invisible laser light generator for generating invisible laser light; a visible light generator for generating visible light; and an optical path visualization component arranged in optical paths of the invisible and visible light, and comprising a first and second incident end and a first outgoing end. The invisible laser light is incident on the first incident end, and the visible light is incident on the second incident end. All of the invisible laser light and at least part of the visible light are emitted in parallel with each other at the first outgoing end. All of the invisible laser light is present in a direction parallel with the optical path of the visible light, and no invisible laser light is present in other directions, so radiation risks are eliminated.

Disclosed herein are system and product embodiments for an optical image splitter with a plurality of triangular image splitters including a plurality of reflective patterns interleaved with a plurality of transmissive patterns and configured to split an image into a plurality of reflected image portions and a plurality of transmitted image portions. The plurality of reflected and transmitted image portions are subsequently split by additional reflective patterns interleaved with a plurality of transmissive patterns and captured by sensors as partial images to be subsequently recombined to form an image.

A projector includes: a light source that emits light of a first color and a second color; a first image formation element that forms a first image light of the first color; a second image formation element that forms a second image light of the second color; a projection lens that projects the first image light and the second image light to the outside; a first optical system that guides light of the first color that is emitted from the light source to the first image formation element, and guides light of the first color from the first image formation element to the projection lens; and a second optical system that guides light of the second color that is emitted from the light source to the second image formation element, and guides light of the second color from the second image formation element to the projection lens; wherein the first optical system has a convex lens between the first image formation element and the projection lens, wherein f-number of the first optical system is greater than f-number of the second optical system.

Disclosed herein is a system and method for facilitating estimation of a spatial profile of an environment based on a light detection and ranging (LiDAR) based technique. In one arrangement, the present disclosure facilitates spatial profile estimation based on directing light over one dimension, such as along the vertical direction. In another arrangement, by further directing the one-dimensionally directed light in another dimension, such as along the horizontal direction, the present disclosure facilitates spatial profile estimation based on directing light in two dimensions.

Systems, devices, apparatuses and methods for formation of multiple separate light spots with adjustable intensity due to lossless redistribution of the light energy between the separate spots, and with a variable geometry of the multi-spot pattern; advantageously, for laser processing of materials by focusing the laser radiation on a workpiece. The multi-spot pattern is created due to angular polarization splitting of the light beam into several beamlets using a beam splitter and further focusing these beamlets onto a workpiece by a focusing optical system, advantageously by the scanning focusing optics. The beam splitter can include optical birefringent prisms, prism groups and waveplates capable to operate simultaneously at two different wavelengths. Some of these optical elements are rotatable, and their rotations are used for lossless redistribution of light energy between the spots and for a change in the geometric shape of the multi-spot patterns. Embodiments can provide various geometrical configurations of 2, 3, 4, 9 and more separate focused spots: linear, rhombus-shaped, square, parallelogram, rectangular patterns composed in the form of a line or a matrix, with the ability to vary portions of the light energy at the specified separate spots.

A display device includes: a first coupling-in module configured to couple first image light into a light guide assembly at a preset first incident angle, thereby enabling the first image light to propagate in the light guide assembly by total reflection and to be incident in a coupling-out light-splitting module; a second coupling-in module configured to couple second image light into the light guide assembly at a preset second incident angle, thereby enabling the second image light to propagate in the light guide assembly and to be incident in the coupling-out light-splitting module; a coupling-out light-splitting module configured to, couple the first and second image light out from the light guide assembly to enter a first position area and a second position area of the human eye, respectively. The first and second image light are different light field information of an identical image; and are both collimated light.

A multi-function imaging system comprises a light sensor and a software defined light source to enable real-time automatic adjustment of various parameters of the one or more light sources. The system is realized in a single unit, or as multiple co-located units, thus reducing the cost of having such multiple functions. The system is capable of self-calibrating in the field to enable accurate imaging.

A beam separator has a composite prism having an external input face and an external output face co-planar to the input face. At least one polarization beam splitter surface is encased within the composite prism and has an edge that defines a boundary between the external input face and the external output face. A first reflective surface is disposed to redirect, along a direction orthogonal to the input face, light of a first polarization that reflects from the at least one polarization beam splitter.

A module accommodates multiple superluminescent light emitting diodes, SLEDs, 12r, 12g and 12b. The SLEDs are arranged in an enclosure and output respective light beams to propagate into free space within the enclosure. The individual light beams from the SLED sources are combined into a single beam path within the enclosure using beam combiners 40r-g, 40rg-b. Each beam combiner is realized as a planar optical element, the back side of which is arranged to receive a SLED beam and route it through the optical element to the front side where it is combined with another SLED beam that is incident on and reflected by the front side. The free-space propagating combined beam is output from the module via an optical fiber 42 (or through a window).