A coupling element for a positioning device, which includes a first and second linear guides for guiding first and second carriages respectively along first and second linear directions, is configured to create a coupling between the first carriage and the second linear guide. The coupling element includes a central part and a surrounding part spaced at a distance therefrom. The surrounding part has a central portion surrounding the central part, and has two end portions adjoining the central portion in the first linear direction. Connecting flat springs are disposed to create the distance and connect together the central part and the central portion of the surrounding part. The connecting flat springs lie in planes which intersect at a center of the central part. A vertical flat spring is disposed parallel to the first linear direction at each of the two end portions of the surrounding part.

An optical unit with shake-correction function is provided. A rotational support structure for supporting a movable body including a camera module around an optical axis is rotatably supported around a first axis and a second axis by a gimbal mechanism. The rotational support structure includes: a first annular groove, provided in the movable body; a plate roller, having a second annular groove facing the first annular groove in a direction of a Z axis; and a plurality of spherical objects, configured to be inserted into the first annular groove and the second annular groove, and roll between the movable body and the plate roller. The gimbal mechanism is configured to rotatably support the plate roller around the first axis.

An optical detection apparatus is provided. The optical detection apparatus includes a light emitting unit, a light receiving unit, a storage unit, and a determining unit. The light emitting unit includes a plurality of light-emitting elements. The light receiving unit includes a light-receiving element arrayformed by a plurality of light-receiving pixels, which receive reflected light corresponding to emitted light of the light emitting unit. The storage unit stores a reference light-receiving region on the light-receiving element array corresponding to a location of occurrence of light intensity unevenness included in the emitted light of the light emitting unit. The determining unit determines an optical axis misalignment using a positional displacement between the reference light-receiving region and a detected light-receiving region of light intensity unevenness included in the reflected light of the emitted light on the light-receiving element array.

A multi-group lens assembly (10), a camera module (100), and an electronic device (200) therefore are provided. The multi-group lens assembly (10) includes at least two group units (11 and 12). At least a first gap (15) is provided between the at least two adjacent group units (11 and 12) to compensate a difference between the multi-group lens assembly (10) and an optical design system, thus allowing an optical system of the multi-group lens assembly conform to the optical design system of the present invention.

The present teachings provide an image capture device including a bayonet and an integrated sensor and lens assembly (ISLA). The bayonet is connected to a body of the image capture device. The ISLA is connected to the bayonet. All or a portion of the ISLA extends into the body of the image capture device. The ISLA includes a lens assembly having a forward end and a rearward end and an integrated sensor. The integrated sensor is connected to the rearward end of the lens assembly. Fasteners extend through the bayonet into the forward end of the lens assembly to connect the ISLA to the bayonet.

A scanner for scanning a dental site comprises a base, a detector mounted to the base, and an optical element to redirect light reflected off of the dental site towards the detector along a detection axis in a first direction. Two or more flexures couple the optical element to the base, wherein thermal expansion or contraction of the optical element with respect to at least one of the detector or the base bends each flexure of the two or more flexures in a respective second direction without bending the flexure in a respective third direction approximately perpendicular to the first direction and the respective second direction, wherein the two or more flexures maintain an alignment of the optical element to the detector with changes in temperature.

Provided are a camera module, a camera lens with a mark and a manufacturing method thereof, and an assembly method of an extra-wide-angle camera module. The camera module includes a camera lens and a photosensitive assembly. The camera lens includes a lens tube, at least one first lens unit, at least one second lens unit and at least one mark element. The first lens unit and the second lens unit are provided in the lens tube. The first lens unit is a non-rotational member. The mark element is provided at the lens tube, and is used to position the first lens unit.

An optical setup, comprising one or more platforms having a plurality of fixation locations repeatedly arranged, and defining a discrete position coordinate system; and a plurality of modular optical units, each comprising an optical portion defining an optical axis fixedly attached to at least one mounting surface comprising complementary geometry to the fixation locations; wherein a releasable attachment of the plurality of modular optical units at the fixation locations defines a plurality of optical axes at least a portion of the optical axes overlapping across the discrete position coordinate system In some embodiments, the modular optical units include standard optical elements In some embodiments, the platform includes an attachment interface to an optical table and/or another platform In some embodiments, laser pulses are synchronized by fixing a discrete path length over the fixation locations In some embodiments the fixation locations are located on multiple planes in 3D space.

A vehicular camera assembly includes an imager printed circuit board (imager PCB) having an imager disposed at a first side of the imager PCB. A lens barrel accommodates a lens and has an inner end. The inner end of the lens barrel is disposed at a first portion of a camera housing. The imager PCB is attached at a second portion of the camera housing that joins with the first portion so that the imager faces the lens. The second portion is adjustable relative to the first portion to align the imager and the lens. With the second portion engaging the first portion and the imager and lens aligned, a weld washer is laser welded to the first and second portions to join the second portion to the first portion.

A method for aligning a camera lens with a light source is provided. The method is used in an aligning system. The aligning system includes an alignment element, a reference camera and a fixture. Firstly, the reference camera shoots a reference chart on the alignment element. Then, the light source is placed on the fixture. The light source illuminates the alignment element to generate an illumination result. The reference camera shoots the illumination result. If the illumination result does not comply with a preset specification represented by the reference chart, the fixture adjusts the light source. Then, the camera lens is placed on the fixture. Then, the camera lens shoots the reference chart on the alignment element to acquire a shooting result. If the shooting result does not comply with the preset specification, the fixture adjusts the camera lens.