A camera assembly can include a housing that includes a front side that includes a front side perimeter, a back side that includes a back side perimeter, and a surface that extends between the front side and the back side; a camera that includes a front side aperture; a front side illumination light; and a status light.

A double chamber camera is provided. The double chamber camera may include: a housing having an upper chamber and a lower chamber; and an upper chamber assembly arranged in the upper chamber, and a lower chamber assembly arranged in the lower chamber. The upper chamber assembly may include a first monitoring lens and a first transmission module. The first monitoring lens may be a zoom lens. The first transmission module may include a first support and a second support rotatably matched with the first support, a first driving unit configured to drive the first support to rotate along a first direction, and a second driving unit configured to driving the second support to rotate along a second direction. The first monitoring lens may be fixed on the first support or the second support.

In a vehicle camera device, a camera is housed inside a bracket of a base, and a stud bolt of the base is connected to a side door. Heat generated by the camera is transferred to the side door via the bracket, the base, and the stud bolt. Therefore, the heat generated by the camera can be efficiently released from the camera.

Described herein are lightboxes and methods of use for the digital preservation of historical collections. The lightbox includes abase, the base having a grid visible on at least one surface of the base, and a plurality of walls extending above and substantially perpendicular to the base. A support platform having an aperture therein is located within the plurality of walls and above the base and is secured in the lightbox via a height adjustment mechanism. A cover is positioned above the base and below the support platform and secured in the lightbox via one or more hinge mechanisms One or more lighting elements are positioned along one or more walls of the lightbox, each lighting element including at least one light.

An ultrasonic penetrometer may include an enclosure, an ultrasonic sensor, and a rod. The enclosure may include a channel having a first end and a second end. The ultrasonic sensor may be provided at the first end of the channel and may be configured to generate an ultrasound signal through the second end of the channel. An output from the ultrasound sensor may be used to determine a thickness or stiffness of sediment. The rod may have a proximal end facing the ultrasonic sensor and a distal end opposite the proximal end. The rod may be configured to move relative to the enclosure. The distal end may be configured to contact the sediment. The enclosure may be configured to be fluid-tight relative to an exterior of the enclosure such that the generated ultrasound signal travels in a single medium.

A camera apparatus includes a camera body portion including a prism unit, a lens assembly, and an image sensor unit, a gyro sensor detecting a hand-shake with respect to the camera body portion and outputting gyro sensor information, a driver circuit generating at least one of a prism driving signal for image stabilization of the prism unit and a sensor driving signal for image stabilization of the image sensor unit based on the gyro sensor information, a prism actuator disposed in the camera body portion for driving the prism unit and performing image stabilization on the prism unit in response to the prism driving signal, and a sensor actuator disposed in the camera body portion for driving the image sensor unit and performing image stabilization on the image sensor unit in response to the sensor driving signal.

A system can include a display assembly that includes a display, a display side, a back side and a frame, where the back side includes a serial bus socket; and a camera assembly that includes a camera head unit coupled to an end of an arm, where an opposing end of the arm includes a serial bus connector receivable by the serial bus socket of the back side of the display assembly.

A system can include a display assembly that includes a display, a display side, a back side and a frame, where the back side includes a serial bus socket; and a camera assembly that includes a camera head unit coupled to an end of an arm, where an opposing end of the arm includes a serial bus connector receivable by the serial bus socket of the back side of the display assembly.

An electronic device includes a display including a panel layer in which a plurality of pixels are disposed, and a camera module disposed under the display, where the camera module includes an image sensor and a plurality of lenses, and an optical axis of the plurality of lenses passes through the panel layer. A coating layer, which lowers reflectance, is formed on a lens surface of the plurality of lenses when an angle of slope of a partial area of the lens surface is within a specified range. The angle of slope is an angle formed by the lens surface with a normal line perpendicular to the optical axis.

Various techniques are provided for prevent excessive accumulation of moisture onto a surface of an optical component of an imaging device. In one example, a method includes providing a bulk layer of an optical component of a thermal imaging system, wherein the bulk layer is configured to pass thermal radiation. The method further includes depositing a diamond like coating (DLC) to provide an external surface of the optical component, wherein the DLC exhibits a resistance to abrasion. The method further includes forming a plurality of nanostructures in the optical component, wherein the nanostructures exhibit a superhydrophobic property to prevent excessive moisture accumulation on the external surface of the optical component. Additional methods and systems are also provided.