Speckle artifacts as viewed in images projected on a display surface by a projector can be reduced. At least one spatial light modulator, illuminated by one or more light sources, can be imaged to a screen by a projection lens. A deflector subsystem can be provided in image space, proximate to the lens, where the image light emerges. In this location, image light directed to any given field point on the display surface is convergent, but can appear collimated. The deflector subsystem can include a tilted optical plate that is rotated in a plane along an axis. As the deflector subsystem is temporally rotated, the image light to any given field point traverses different optical paths, varying the angular diversity to reduce perceivable speckle by changing at least the angle of incidence to the screen.

A digital exposure apparatus includes a lens array, the lens array at least including a first lens unit and a second lens unit, a light transposition assembly arranged on an exit light path of the second lens unit, and the light transposition assembly being used for controlling a light exiting from the second lens unit to be transposed with respect to an exposure direction of the digital exposure apparatus. When the digital exposure apparatus is used for exposure, a light passing through the first lens unit and a light penetrating through the second lens unit are needed to expose the same position for multiple times.

An imaging correction unit and an imaging module are provided. The imaging correction unit has an optical axis and includes four wedge optical elements with the same structure. The wedge optical elements are disposed sequentially on the optical axis. Each of the wedge optical elements has a minimum thickness dimension at a first edge and a maximum thickness dimension at a second edge. A connection line between the first edge and the second edge forms a symmetry axis of the each of the wedge optical elements. When a beam transmitted along the optical axis of the imaging correction unit passes sequentially through the wedge optical elements and is imaged at a center of an imaging surface, the symmetry axis of any one of the four wedge optical elements is at an angle of 90 degrees relative to the symmetrical axis of one of adjacent wedge optical elements.

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.

An optical module for imaging light emitting objects on an image sensor comprises a polarizing beam splitter having an entrance face, an exit face, first and a second return faces, a first reflector facing the first return face, a first achromatic quarter-wave retardation plate between the first return face and the first reflector, a second reflector facing the second return face, and a second achromatic quarter-wave retardation plate between the second return face and the second reflector. The first and second reflectors differ in at least one of their orientation with regard to the first and second return faces or their spectral properties. At least one of the first reflector and the second reflector comprises a dichroic mirror arranged between the respective achromatic quarter-wave retardation plate and a further mirror of the respective reflector. The dichroic mirror is tilted with regard to the further mirror of the respective reflector.

Embodiments of the disclosure provide a transmitter containing a Risley prism-based scanning mechanism, an optical sensing system containing the same, and an optical sensing method using the same. For example, the optical sensing system includes a laser emitter configured to sequentially emit a series of optical signals. The optical sensing system further includes a plurality of prisms configured to receive the series of optical signals and sequentially direct the series of optical signals at different directions in an angle of view of the optical sensing system. At least one prism of the plurality of prisms is configured to rotate relative to at least one other prism of the plurality of prisms to refract the optical signals towards the respective different directions. The optical sensing system additionally includes a receiver configured to receive at least a portion of the series of optical signals reflected from an environment surrounding the optical sensing system.

An optical device for machine vision, particularly for automatically extracting information from images of an object, comprising: a first optical path, which is arranged to image a first object plane, a second optical path, which is arranged to image a second object plane, an image sensor which is arranged to capture the image of the first and/or second object plane, wherein the first object plane extends obliquely with respect to the second object plane, the first optical path and the second optical path extend through a first liquid lens with an optical axis, wherein the optical axis extends vertically.

Motors for driving multi-element optical scanning devices and associated systems and methods include an exemplary optical system. The optical system includes at least one optical element positionable along an optical path to receive radiation, with the at least one optical element having an opening therethrough; a shaft extending through the opening; at least one bearing operably coupled to the shaft; and a motor operably coupled to the at least one optical element to rotate the at least one optical element.

Embodiments of the present specification provide an apparatus for detecting an angle of rotation of a rotating member. A light source emits light rays which are conditioned by a light conditioner to control a light beam geometry and emission pattern of the light rays. The conditioned rays are incident on an optical disk that emits refracted rays in form of a light spot on an optical detector. The optical disk rotates in synchronization with the rotating member. The optical detector uses position of the light spot to output an analog signal continuous and ratio-metric to the angle of rotation of the rotating member.

A star tracker includes imaging optics comprising a folding mirror, a lens, and a detector. The folding mirror bends light received from an optical axis through the lens that focuses the bent light onto the detector. The star tracker includes a steering mechanism that steers light from an adjustable field of view (FOV) to the optical axis of the imaging optics. The steering mechanism includes: (i) a first photonic crystal element comprising beam pointing spatially variant photonic crystals (SVPCs); (ii) a second photonic crystal element comprising beam pointing SVPCs that is positioned adjacent and axially aligned with the first photonic crystal element; and (iii) a housing that receives the first and second photonic crystal elements for independent rotation.