A device for the spherical orientation of an optical element is provided comprising a support structure, the optical element having an optically useful surface adapted to interact with an incident light beam, a mechanism mounted on support structure and capable of rotating the optical element in space around a first and second rotation axis perpendicular to each other.

The mechanism comprises a first rotating assembly around the first rotation axis and a second rotating assembly around the second rotation axis, which first rotating assembly has a through cavity defined around the first rotation axis, the through cavity being adapted to be crossed by the light beam and facing the optical element.

The mechanism comprises at least a first electromagnetic actuator arranged to rotate the first rotating assembly and at least a second electromagnetic actuator arranged to rotate the second rotating assembly.

An assembly (10) for generating a laser beam (12) includes a beam steering assembly (18); a laser assembly (16) that is tunable over a tunable range; and a controller (20). The laser assembly (16) generates a laser beam (12) that is directed at the beam steering assembly (18). The controller (20) dynamically controls the beam steering assembly (18) to dynamically steer the laser beam (12) as the laser assembly (16) is tuned over at least a portion of the tunable range. As a result thereof, the laser beam (12) is actively steered along a desired beam path (12A) while the wavelength of the laser beam (12) is varied.

A beam guide guides a laser beam on a device for extreme ultraviolet lithography. The beam guide has a scraper mirror for coupling out laser radiation and a positioning device for positioning the scraper mirror in a positioning plane defined by first and second positioning axes. The positioning device contains first and second positioning units assigned to the first and second positioning axes, respectively. The first positioning unit has a first linear guide and a first positioning drive. By the first positioning drive, the scraper mirror is moved together with the mirror-side guide element of the first linear guide relative to the mirror-remote guide element of the first linear guide along the first positioning axis into a target position. The second positioning unit has a second linear guide and a second positioning drive, the second linear guide has a mirror-side guide element and a mirror-remote guide element.

LiDAR system and methods discussed herein use a dispersion element or optic that has a refraction gradient that causes a light pulse to be redirected to a particular angle based on its wavelength. The dispersion element can be used to control a scanning path for light pulses being projected as part of the LiDAR's field of view. The dispersion element enables redirection of light pulses without requiring the physical movement of a medium such as mirror or other reflective surface, and in effect further enables at least portion of the LiDAR's field of view to be managed through solid state control. The solid state control can be performed by selectively adjusting the wavelength of the light pulses to control their projection along the scanning path.

An optical element driving mechanism is provided and includes a movable portion and a fixed portion. The movable portion includes a carrier for carrying an optical member with a first optical axis. The fixed portion has a top surface, a first side surface and a second side surface. The top surface extends in a direction that is parallel to the first optical axis. The first side surface and the second side surface extend in a direction that is not parallel to the first optical axis from the edge of the top surface and face different sides of the optical member. The shortest distance between the optical member and the first side surface is shorter than the shortest distance between the optical member and the second side surface.

A method and an apparatus for collecting powder samples in real-time in powder bed fusion additive manufacturing may involves an ingester system for in-process collection and characterizations of powder samples. The collection may be performed periodically and uses the results of characterizations for adjustments in the powder bed fusion process. The ingester system of the present disclosure is capable of packaging powder samples collected in real-time into storage containers serving a multitude purposes of audit, process adjustments or actions.

A laser scanner that includes a transmission path and a reception path that is spatially separate from the transmission path, at least in areas. In the laser scanner, the transmission path and the reception path meet on opposite sides of an angularly movable deflection mirror of the laser scanner. An angular position of the deflection mirror in the transmission path defines a scan angle of a laser light of the laser scanner, and the angular position in the reception path compensates for an incidence angle of a reflection of the laser light.

A periscope optical module is provided. The periscope optical module includes a first optical element, a second optical element, and a third optical element. The first optical element has a first optical axis. The second optical element corresponds to the first optical element and adjusts a forward direction of a light. The third optical element has a second optical axis. The third optical element corresponds to the second optical element. The light passes through the first optical element, the second optical element, and the third optical element consecutively. The first optical axis is not parallel to the second optical axis. A minimum size of the first optical element in a direction that is perpendicular to the first optical axis is larger than a maximum size of the third optical element in a direction of the first optical axis.

A network device generates first resonant light used to carry information; and the network device sends the first resonant light to a terminal by using a resonant cavity component, where the resonant cavity component of the network device and a resonant cavity component of the terminal form an open resonant cavity. In wireless optical communication, an information transmission rate can be greatly improved by using a resonant light multiplexing technology. This application further discloses a network device and a terminal that can implement the foregoing wireless optical communication method.

An inspecting apparatus includes a table for supporting a workpiece thereon, a light applying unit for applying light to the workpiece supported on the table, and a light detector for detecting light reflected from the workpiece. The light detector includes a camera and a diffusion plate disposed between the table and the camera.