A driving mechanism is provided, including a base, a movable module, and a driving assembly. The movable module has a movable member and a connecting member connected to the movable member. The driving assembly is connected to the base and the connecting member. The driving assembly has a driving element that generates a driving force to the connecting member and the movable member, so that the movable module moves relative to the base.

A lens device includes a first lens module, a first light path turning module and an image sensor. The first lens module, the first light path turning module and the image sensor are sequentially arranged along a light path in which a light beam propagates. The first light path turning module is configured to change a direction in which the light beam propagates so that the light beam passes through the first lens module to form an image on the image sensor.

A lens apparatus includes an holding barrel configured to hold a lens, movable relative to a fixed barrel in an optical axis direction, and configured to form a retracted state having an overall length of the lens apparatus smaller than when the lens apparatus is in an imaging state, an operating member configured to switch between a lock state that locks the holding barrel and an unlock state that unlocks the holding barrel, a state detector configured to detect a state of the holding barrel relative to the fixed barrel in the optical axis direction, a lock detector configured to detect whether the operating member is in the lock state or the unlock state, and an output unit configured to output detection results by the state detector and the lock detector, or information on whether imaging is available according to the detection results.

A lens positional adjustment device having a lens mounted to a moveable lens body, with the lens body including a bearing member and the lens mounted to the body to enable a laser beam to be projectable at and through the lens. A first voice coil member is mounted to the lens body and is axially offset from the optical axis of the lens. The device also includes a housing having a second voice coil member and a housing bearing with the bearing member of the lens housing being engaged with the housing bearing. The voice coil members are constructed to be one of an electrical coil winding and a magnet that engage to enable movement of the lens body relative to the housing when a current is supplied to the electrical coil winding whereby movement of the lens body relative to the housing adjusts the position of the lens.

A sight includes a compensating mechanism. The compensating mechanism includes a base unit, a displaying unit, an adjusting cap and a first transmission unit. The displaying unit is disposed on the base unit and includes a mark. The adjusting cap is disposed outside the displaying unit and includes an information displaying portion for showing the mark. The first transmission unit is connected to the adjusting cap and the displaying unit. The adjusting cap is connected to the transmission unit and includes a groove. When the adjusting cap is rotated with respect to the base unit about an axis, the information displaying portion is synchronously rotated with the adjusting cap and the first transmission unit drives the displaying unit to move along the axis so as to change the mark shown by the information displaying portion.

An optical assembly includes an optical element including a reflection surface to reflect light in a first axis direction, a holder to hold the optical element, a case to support the holder, a first swing mechanism to swing the holder around a first swing axis, and a second swing mechanism to swing the holder around a second swing axis perpendicular to the first swing axis. The holder includes first and second protrusions. The case includes first and second recesses. Each of the recesses includes a first side surface located on one side in the axial direction of the second swing axis and a second side surface located on the other side with respect to the corresponding protrusion. At least one of the first and second side surfaces includes an inclined surface inclined with respect to the second swing axis.

An imaging device includes a lens barrel in which a plurality of lenses are held and that has a thread groove in a cylindrical outer periphery thereof; an imaging element that captures a subject image incident on the imaging element through the lenses; a housing that holds the imaging element and that includes a threaded portion configured to engage with the thread groove in the outer periphery of the lens barrel; and an adhesive member positioned between the thread groove in the outer periphery of the lens barrel and the threaded portion of the housing. The thread groove is provided in a range including a position at which a principal plane of an optical system including the plurality of lenses crosses the outer periphery of the lens barrel.

A lens housing, a lens module and a light source system are disclosed. The lens housing includes a lens holder, a leans barrel, and a fixed pressing plate. The lens holder includes an accommodating cavity having an internal thread. The lens barrel is provided with a receiving cavity along an axial direction and includes an adjustment structure along a circumferential direction. An outer circumferential wall of the lens barrel is provided with an external thread matching the internal thread. The lens barrel is embedded in the accommodating cavity of the lens holder and is in threaded connection with the lens holder. The fixed pressing plate is fixed to one side of the lens barrel away from the lens holder and is capable of moving axially relative to the lens holder.

An actuator aligned multi-channel projector assembly generates image light using a plurality of projectors. A projector includes a plurality of optical components in optical series and one or more actuators. The plurality of optical components include a light source and a plurality of optical elements. The light source generates first light. The plurality of optical elements project the first light. The first light is output from the projector and combined with a second to form an image presented via a display element of a headset to a user. The one or more actuators adjust a position of at least one optical component of the plurality of optical components relative to another optical component in order to compensate for misalignment of a portion of the image formed from the first light relative to a portion of the image formed from the second light.

An optical mechanism comprises a fixed portion with a main axis, wherein the fixed portion has a polygonal structure when viewed along the main axis; a movable portion, moving relative to the fixed portion, connected to an optical element; a joining mechanism, wherein the movable portion is movably connected to the fixed portion via the joining mechanism. The joining mechanism comprises a resilient member, having a longitudinal structure, extending in a first direction that is parallel to the main axis; and a spring sheet, having a tabular structure, wherein the spring sheet is movably connected to the fixed portion via the resilient member. The spring sheet comprises a connecting portion, fixedly connected to the movable portion; a fixing portion, accommodating the resilient member; a first section; and a second section. The first section comprises a first part with a first width; and a second part with a second width, wherein the first part is connected to the connecting portion via the second part. The second section comprises a third part with a third width; and a fourth part with a fourth width, wherein the third part is connected to the connecting portion via the fourth part. The first part is connected to the third part via the fixing portion. The first width is smaller than the second width. The third width is smaller than the fourth width. The first part and the third part extend in different directions.