The disclosure is directed to a power source for one or more firearm optical sighting systems. The power source includes a solar powered cap assembly operationally configured to electrically communicate with one or more firearm optical sighting systems.

The disclosure is directed to a power source for one or more firearm optical sighting systems. The power source includes a solar powered cap assembly operationally configured to electrically communicate with one or more firearm optical sighting systems.

Certain aspects of a novel weapon sight system combine a direct view, a visible light video view, and an infrared (IR) video view mode. Each of the view modes may be viewed individually or simultaneously with one or more of the other view modes through a single viewing aperture. Further, the one or more view-modes may be provided while providing a bore-sighted reticle superimposed on the selected view. Further, the reticle may be powered separately from the video view electronics enabling use of the reticle regardless of the power status video view electronics.

A shape memory alloy actuator arrangement for a movable element supporting a camera lens assembly comprises plural shape memory alloy actuator wires connected between a support structure and the movable element in an arrangement wherein the shape memory alloy actuator wires are arranged, on selective driving, to move the movable element relative to the support structure in any direction orthogonal to the optical axis of the at least one lens. At least one plain bearing bears the movable element on the support structure, allowing movement of the movable element relative to the support structure orthogonal to the optical axis.

An electronic device may be provided with optical markers. A marker may be formed from a coating. The coating may be patterned to form a two-dimensional optical code or may be patterned to form an outline or other recognizable marker structure that helps provide information about an electronic device. A device with a sensor such as a depth sensor or other sensor may gather information on the electronic device and its markers. This information may include information on images captured with an image sensor while the electronic device is illuminated by one or more light beams from the depth sensor or other light sources. Markers may be configured to serve as mixed reality optical markers in a mixed reality system. Analysis of the mixed reality marker images or other sensor data may reveal information on device type, device location, device size, device orientation, and other information on a marked device.

An electronic device may be provided with optical markers. A marker may be formed from a coating. The coating may be patterned to form a two-dimensional optical code or may be patterned to form an outline or other recognizable marker structure that helps provide information about an electronic device. A device with a sensor such as a depth sensor or other sensor may gather information on the electronic device and its markers. This information may include information on images captured with an image sensor while the electronic device is illuminated by one or more light beams from the depth sensor or other light sources. Markers may be configured to serve as mixed reality optical markers in a mixed reality system. Analysis of the mixed reality marker images or other sensor data may reveal information on device type, device location, device size, device orientation, and other information on a marked device.

A holographic weapon sight with a low profile collimator has a housing with a viewing end and an opposed target end. The holographic weapon sight has a light source operable to project a light beam along a light path. The low profile collimator has a first optical element and a second optical element disposed in the light path of the light beam such that the second optical element provides a fully collimated light beam. The holographic weapon sight also has a first diffractive optical element (DOE), a second DOE, and a mirror. The first DOE or the second DOE reconstructs an image of a reticle and respectively reflects the reconstructed image toward the mirror or the NDE such that a user views a target along a viewing path through the NDE from the viewing end.

An illuminator including a light source and an optical device is provided. The light source is configured to emit light. The optical device is configured to provide uniform illumination with at least one indicating mark after receiving light. The optical device includes a diffusing part and a directing part. The diffusing part is configured to provide uniform illumination. The directing part is configured to provide at least one indicating mark.

A holographic sight comprises a base, a support member attached to the base and extending upward therefrom, and a unitary optical component carrier formed with the support member. The support member is flexible and the unitary optical component carrier moveable in horizontal and vertical directions relative to the base. A bridge is attached to the base and forms an opening into which a portion of the unitary optical component carrier extends. A projection is coupled with the bridge and protrudes into the opening to abut the unitary optical component carrier. Extending the projection into the opening increases pressure applied by the projection to the optical component carrier. The increased pressure causes the unitary optical component carrier to be displaced.

A transparent thin film electroluminescent display device includes a first transparent thin film electroluminescent display having a substrate and a first active layer capable of emitting a spectrum of light in a wavelength of visible light. The transparent thin film electroluminescent display device further includes a second transparent thin film electroluminescent display having a substrate and a second active layer, the first and second transparent thin film electroluminescent displays being arranged in a superposed manner such that the first and second active layers are spaced apart from each other for forming the transparent thin film electroluminescent display device with a superposed structure.