An optical system for use with a vacuum chamber may include a target to be positioned within the vacuum chamber, a laser source, and an optical assembly to be positioned within the vacuum chamber between the target and the laser source. The optical assembly may include a housing, a frame, a lens carried by the frame, and spiral flexures each having a respective proximal end coupled to the frame. In addition, the optical assembly may include a plurality of flexure actuators, where each flexure actuator is coupled between the housing and a distal end of a respective spiral flexure.

A lens shift mechanism of one embodiment of the present disclosure includes: a projection lens; a cylindrical housing that holds the projection lens; and an operating unit that moves the cylindrical housing in one axial direction perpendicular to an optical axis of the projection lens. The operating unit includes a pair of a main shaft and a countershaft extending in the one axial direction and disposed to be opposed to each other across the cylindrical housing, and a pair of elastic bodies provided respectively for the main shaft and the countershaft. The pair of elastic bodies are parallel to the one axial direction, and have biasing directions opposite to each other.

For checking the confocality of a scanning and descanning microscope assembly comprising a light source providing illumination light focused into a focal area in a focal plane, a detector detecting light coming out of the focal area and having a detection aperture to be arranged in a confocal fashion with respect to the focal area, and a scanner, an auxiliary detection aperture of an auxiliary detector arranged in the focal plane is scanned with the focal area of the illumination light to record a first comparison intensity distribution of the illumination light registered by the auxiliary detector, and the detection aperture of the detector is scanned with auxiliary light that exits out of an auxiliary emission aperture of an auxiliary light source concentrically arranged with respect to the auxiliary detection aperture in the focal plane to record a second comparison intensity distribution of the auxiliary light registered by the detector.

Embodiments comprise a system created through fabricating a lens array through which lasers are emitted. The lens array may be fabricated in the semiconductor substrate used for fabricating the lasers or may be a separate substrate of other transparent material that would be aligned to the lasers. In some embodiments, more lenses may be produced than will eventually be used by the lasers. The inner portion of the substrate may be formed with the lenses that will be used for emitting lasers, and the outer portion of the substrate may be formed with lenses that will not be used for emitting lasers—rather, through etching these additional lenses, the inner lenses may be created with a higher quality.

A system includes a compound flexure having a frame, a flexure, and a post flexure. The frame has an axis, and the flexure is located within the frame. The flexure is movable relative to the frame, and the frame and the flexure form at least part of a monolithic structure. The post flexure extends along the axis and engages the flexure. The system also includes a device coupled to the flexure and configured to move with the flexure relative to the frame. The system further includes an actuator coupled to the flexure and configured to move the flexure and the device relative to the frame.

Techniques are described for aligning optical components within a LIDAR assembly. The techniques may be performed to align the optical components during manufacturing or assembly of the LIDAR assembly. For example, a first optical element (e.g., one of a light source or light sensor) may be installed in the LIDAR assembly. An optimal alignment for a second optical element (e.g., the other of the light source or light sensor) may be determined and the second optical element may be installed at the optimal alignment. The optimal alignment for the second optical element may be determined based on detected signals, for example, which may correspond to an alignment resulting in a strongest return signal, highest quality return signal, and/or minimal interference. Additionally or alternatively, techniques may be used to align optical components at runtime by using an actuator to move one or more components of the LIDAR assembly during operation.

A device for moving a nonlinear crystal or a saturable absorber in two dimensions includes a first and a second piezo unit, each having a corresponding carrier, piezo driver, and carriage moveable by the piezo driver at incremental steps along a linear path with respect to the carrier between a first and a second end location, in which the linear paths of the first piezo unit and the second piezo unit are orthogonal. The nonlinear crystal/saturable absorber is fastenable on the carriage of the first piezo unit and the carrier of the first piezo unit is fastened on the carriage of the second piezo unit. The device further includes stops that define the carriage end locations, an end location detection configured to detect the carriages at their respective end locations, and a counting unit configured to count the steps covered during the moving of the carriage.

The disclosure relates generally to techniques for determining pupil location of a display device's user via imaging sensors on the display device, and using that information to verify and/or correct positioning of the display device or its internal components. The display device may be a head-mounted display (“HMD”) device with display panels separated from a wearer's eyes via intervening lenses, with the sensors including optical flow sensor integrated circuits mounted on or near at least one of the display panels to capture images of the wearer's eye locations through the lenses, and with the correction to the positioning including modifications to the alignment or other positioning of the HMD device on the wearer user's head and/or its internal components within the HMD device (e.g., based on automated control of motors on the HMD device) to reflect a target alignment of the wearer's eyes relative to displayed information.

The invention concerns an adjustment system for aligning optical elements and/or samples in vacuum (3) for projecting electromagnetic radiation in the terahertz range up to the range of hard X-ray radiation, consisting of at least one vacuum chamber (3″), at least one mirror (3′) adjustable in spatial direction and/or at least one optical element adjustable in spatial direction or at least one sample adjustable in spatial direction, with translational actuators (X1, X2, Z1, Z2, Z3) in the undeflected state (idle state) being provided for adjusting the alignment of the at least one mirror (3′) adjustable in spatial direction and/or the at least one optical element adjustable in spatial direction or the at least one sample adjustable in spatial direction in a maximum of three essentially mutually perpendicular spatial directions (X, Y, Z, y, y, z).

Pursuant to the invention it is provided that the at least one mirror (3′) adjustable in spatial direction (X, Y, Z, y, y, z) and/or the at least one optical element adjustable in spatial direction (X, Y, Z, y, y, z) or sample within the vacuum chamber (3″) is mounted in a fixed position in relation to the vacuum chamber (3″), with the vacuum chamber (3″) being directly or indirectly connected with the translational actuators (X1, X2, Z1, Z2, Z3) for aligning the spatial position of the mirror and/or the optical element or the sample.

This setup facilitates a very compact and small design of the vacuum chamber and achieves a very high precision of the alignment.

A 3D display system includes a rotational base, a 3D projecting device, an image capturing device, and a controller. The 3D projecting device is rotatably disposed on the rotational base. The image capturing device is disposed on the 3D projecting device. The controller is electrically connected to the image capturing device, the rotational base, and the 3D projecting device.