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.

Disclosed is a mounting structure for a galvanometer motor. The mounting structure includes a motor apparatus directly mounted on a platform, wherein at least one connection through hole running vertically from a top portion of a housing and extending to a bottom portion of the housing is molded on the housing, and the housing is provided with a connection post, wherein the connection post runs through the connection through hole and is fixedly connected to the platform. In this way, an additional mount is not needed, such that mounting cost is reduced, and mounting is accurate and reliable.

A portable photogrammetry studio for digitisation of human body surfaces.

A mirror device includes: a mirror having a rotation shaft and a reflecting surface that reflects display light; a support portion having a cylindrical shape, having a base end fixed and a tip end being a free end, and configured to rotatably support the rotation shaft; and a motor that pivots the mirror, in which the rotation shaft is inserted into the support portion while spreading the support portion outward in a radial direction, and is slidably supported by the support portion.

A micro-electronic non-landing mirror system includes a substrate, at least two supporting assemblies, at least two driving electrodes, a rotating mirror, and a driving circuit. The rotating mirror is elastically supported on the supporting assemblies through elastic reset assemblies. When the driving circuit applies a driving voltage, the rotating mirror moves closer to the driving electrode to which the driving voltage is applied within a range of movement that does not land on the substrate. When the driving circuit removes the driving voltage, the rotating mirror gets back to move away from the driving electrode under elastic restoring force of the elastic reset assemblies. Each elastic reset assembly includes at least two elastic reset units connected to different corners of the rotating mirror by a corresponding one supporting assembly. Each elastic reset unit is configured for providing the rotating mirror with at least two rotational degrees of freedom.

An imaging system for creating an image of a target object comprising a mirror mounted on a gimbal and arranged to rotate about at least one axis, a gimbal drive unit configured to control the orientation of the gimbal, and a camera having its optical axis directed onto the mirror in order that an image reflected in the mirror is within a field of view of the camera, wherein the control unit is arranged to position the gimbal such that a reflection of a target object is within a field of view of the camera.

The invention relates to an optical device (1) for enhancing the resolution of an image, comprising: a transparent plate member (10) configured for refracting a light beam (20) passing through the plate member (10), which light beam (20) projects an image comprised of rows and columns of pixels (40), a carrier (50) to which said transparent plate member (10) is rigidly mounted, wherein the carrier (50) is configured to be tilted between a first and a second position about a first axis (A), such that the plate member (10) is tilted between the first and the second position about the first axis (A), whereby said projected image (30) is shifted by a fraction (ΔP) of a pixel, particularly by a half of a pixel, along a first direction (x), and an actuator means (60) that is configured to tilt the carrier (50) and therewith the plate member (10) between the first and the second position about the first axis (A).

In some embodiments, a depth map acquisition system, includes a housing, a light source for emitting light to illuminate objects in a scene subject to depth mapping, fixedly mounted to the housing, a mirror tilt actuator, fixedly mounted to the housing, for tilting a mirror fixedly mounted to the mirror tilt actuator, a mirror fixedly mounted to the mirror tilt actuator, for reflecting light from the light source to the objects, and a partially transparent photosensitive detector in the direct path of the light from the mirror to the objects.

A lidar system includes one or more light sources configured to generate a first beam of light and a second beam of light, a scanner configured to scan the first and second beams of light across a field of regard of the lidar system, and a receiver configured to detect the first beam of light and the second beam of light scattered by one or more remote targets. The scanner includes a rotatable polygon mirror that includes multiple reflective surfaces angularly offset from one another along a periphery of the polygon mirror, the reflective surfaces configured to reflect the first and second beams of light to produce a series of scan lines as the polygon mirror rotates. The scanner also includes a pivotable scan mirror configured to (i) reflect the first and second beams of light and (ii) pivot to distribute the scan lines across the field of regard.

A reading device includes an emission unit that emits light; a first reflecting unit having a first reflecting surface that reflects the light emitted by the emission unit toward a document; an optical path unit including a second reflecting unit having a second reflecting surface that reflects the light reflected by the first reflecting unit and specularly reflected by the document, the optical path unit defining an optical path that guides the light reflected by the second reflecting surface; an image sensor that generates an image represented by light guided by the optical path unit; and a support unit that supports the first reflecting unit and the second reflecting unit and fixes a relative position and a relative orientation between the first reflecting surface and the second reflecting surface.