A camera includes: a ring-like body mount having an inside diameter smaller than about 48 millimeters; and a solid-state image pickup device arranged oppositely to the body mount, the solid-state image pickup device having a rectangle light receiving section with a diagonal line length of about 43 millimeters or more. An apparent shape of the solid-state image pickup device viewed from a front surface side of the body mount is a rectangle in which one or more corners are oblique.

A vehicle mounted sensor assembly includes a frame and a cover connected to the base. When assembled, the frame and the cover define a volume that is divided between a first cavity and a second cavity. A sensor is disposed in the first cavity and one or more antennas are disposed in the second cavity.

A vehicle mounted sensor assembly includes a frame and a cover connected to the base. When assembled, the frame and the cover define a volume that is divided between a first cavity and a second cavity. A sensor is disposed in the first cavity and one or more antennas are disposed in the second cavity.

An image head including a housing, side rails, a port, and internal componentry. The housing includes a first side and a second side located opposite the second side. The side rails are located on or within the first side, the second side, or both and the side rails are configured to provide sliding directional control of the image head when connecting to a base. The port is configured to electrically connect the image head to the base. The internal componentry includes a printed circuit board; an integrated lens and sensor assembly (ISLA) configured to generate an image; and memory located on the printed circuit board configured to store the image.

In combination with a hand-held firearm comprising a barrel having a longitudinal axis and a muzzle disposed at a distal end of the barrel, the improvement including a secondary viewing device with a housing coupled to the barrel of the firearm and having a first camera retained by, and disposed on a first side of, the housing of the secondary viewing device, disposed substantially adjacent to the muzzle of the firearm, and directed in a viewing orientation substantially orthogonal to the longitudinal axis of the barrel of the firearm for viewing targets lateral to the firearm, the secondary viewing device and the firearm operably configured to have simultaneous and omnidirectional rotation with one another by a user.

The invention relates to an optical device (100) for exposure of a sensor device (10) for a vehicle (1) with an optical structure (101) which comprises an arrangement of optical micro elements (101.1) in order to bundle incident light (2) by the optical micro elements (101.1) and direct the light to sensor elements (10.1) of the sensor device (10) respectively, wherein the optical structure (101) is configured such that light (3) which is directed to the sensor element (10.1) can be concentrated for light active areas (10.2) of the sensor elements (10.1).

This application discloses a stand assembly that includes an upper portion for holding electronic components and a lower portion for supporting the upper portion. The lower portion including a base, a joint, and a second fastener structure configured to mate with a first fastener structure of the upper portion. The first fastener structure and the joint are configured to respectively provide a first degree of freedom of motion and a second degree of freedom of motion of the upper portion with respect to the lower portion. Movement of the upper portion at the first degree of freedom has substantially consistent resistance through first part of a first full range of motion associated with the first degree of freedom of motion. Movement of the upper portion at the second degree of freedom has substantially consistent resistance through a second full range of motion associated with the second degree of freedom.

A sensor apparatus includes a photosensitive sensor, a cover, and a moving mechanism. The photosensitive sensor includes a first lens and a second lens which focus on a photosensitive element. The cover includes a first slit arranged on an optical axis of the first lens and a second slit arranged on an optical axis of the second lens. The moving mechanism is configured to move the photosensitive sensor and the cover relative to each other so that the second slit is arranged on the optical axis of the first lens.

A sensor apparatus includes a photosensitive sensor, a cover, and a moving mechanism. The photosensitive sensor includes a first lens and a second lens which focus on a photosensitive element. The cover includes a first slit arranged on an optical axis of the first lens and a second slit arranged on an optical axis of the second lens. The moving mechanism is configured to move the photosensitive sensor and the cover relative to each other so that the second slit is arranged on the optical axis of the first lens.

The present disclosure relates to devices and methods for detecting and removing vapor for an imaging acquisition device. A device for detecting and removing vapor may include a first light guide. The first light guide may include a first end to receive a light beam, and a second end to output the light beam at a predetermined angle with respect to a reference plane, so that when the light beam enters a target light transmission media from the first light guide, the light beam substantially perfectly reflects between a first surface and a second surface of the target light transmission media. The first surface and second surface may substantially parallel to the reference plane.