This document describes a thermal-control system that is integrated into a security camera. The thermal-control system includes a combination of heatsinks and thermal interface materials with high thermal conductivities. The thermal-control system may transfer and spread energy from a high thermal-loading condition effectuated upon the security camera to concurrently maintain temperatures of multiple thermal zones on or within the security camera at or below prescribed temperature thresholds.

A security system can be configured to mount to a power outlet. The security system can include an outwardly facing portion configured to face away from the power outlet and an inwardly facing portion having a first electrical prong and a second electrical prong that protrude into the power outlet to mount the security system to the power outlet. The security system can also include a detection system comprising a camera and a motion detector.

A device receives position information from a sensor of the device, wherein the position information indicates a position of a user of the device and a position of a person proximate to the user. The device receives lighting information from the sensor, wherein the lighting information indicates lighting conditions around the device and the user. The device calculates a position adjustment for an infrared element of the device based on the position information and the lighting information, and calculates an intensity adjustment for the infrared element based on the position information and the lighting information. The device receives, via an input element of the device, input data provided by the user, and implements the position adjustment and the intensity adjustment to enable the infrared element, when illuminated, to reflect light away from the input element and to prevent image or video capture of the input data.

A computer-implemented method, system, and computer program product is provided for pose-invariant facial recognition. The method includes generating, by a processor using a recognition neural network, a rich feature embedding for identity information and non-identity information for each of one or more images. The method also includes generating, by the processor using a Siamese reconstruction network, one or more pose-invariant features by employing the rich feature embedding for identity information and non-identity information. The method additionally includes identifying, by the processor, a user by employing the one or more pose-invariant features. The method further includes controlling an operation of a processor-based machine to change a state of the processor-based machine, responsive to the identified user in the one or more images.

The present document describes an electronic device with a structural midframe and associated methods. The architectural design of the electronic device (e.g., a security camera) is such that its components are assembled onto the midframe to form a subassembly and the housing is assembled after the subassembly. The midframe includes various features that enable multiple printed circuit boards, a camera subassembly, a front housing member, a heatsink, and a heat spreader to be assembled onto the midframe outside of the housing. The midframe can also include a hinge-bearing surface forming a portion of a ball joint for supporting rotational movement of the electronic device. Accordingly, the electronic device uses the midframe, rather than the housing, as a structural member.

The present disclosure provides a transparent member having a highly reliable hydrophilic film formed thereon which can maintain hydrophilicity for a long period of time, even when a product is packed and stored and when the product is exposed to an outdoor environment, wherein the transparent member is a transparent member including a substrate, a porous layer and a hydrophilic polymer layer in this order, wherein the porous layer contains a silica particle and a binder, and the hydrophilic polymer layer contains a polymer having a zwitterionic hydrophilic group having a layer thickness of 1 nm or larger and 20 nm or smaller.

A dome type surveillance camera includes a planar base, and a plurality of cameras. Each of the plurality of cameras is connected to the base to be movable along a circumference on the base. The plurality of cameras includes three or more cameras. Each of the plurality of cameras is rotatable in both right and left directions with an imaging direction. The imaging direction is an optical axis direction of each of the plurality of cameras as an axis such that a panoramic image formed by images captured by each of the plurality of cameras is continuous in a horizontal direction when the plurality of cameras are disposed so as to be equidistant to each other on a semicircular arc.

A dome type surveillance camera includes a base, a plurality of cameras, a first connecting section, a plurality of second connecting sections, a hemispherical cover fixed to the base, and a circular rail. The first connecting section is connected on the base and connected with one first camera out of the plurality of cameras. The second connecting sections are connected on the base and connected with each of a plurality of second cameras excluding the first camera out of the plurality of cameras. The cover is disposed to cover the first connecting section, the second connecting sections, and the plurality of cameras. The rail is provided on the base and of which a center is immediately below a top of the cover.

A surveillance and lighting system utilizing an existing electricity wiring for its power supply includes imaging and lighting devices and a network video recorder (NVR) wirelessly coupled with the imaging and lighting devices. Each imaging and lighting device has an imaging member operably in an on-state or an off-state; a lighting member operably in an on-state or an off-state; a microcontroller unit coupled with the imaging member and the lighting member for controlling operations of each of the imaging member and the lighting member in a respective state in accordance with an operation mode of said imaging and lighting device, and a power module coupled between the microcontroller unit and a standard AC power source for converting an AC power of the standard AC power source to at least one DC power.

A surveillance camera is a dome type surveillance camera and includes a base, a connecting member connected to the base, a plurality of cameras connected to the connecting member such that imaging directions of the cameras move in an elevation angle direction with respect to the base, and a dome type cover fixed to the base so as to cover the connecting member and the plurality of cameras. One camera, out of the plurality of cameras, moves such that the imaging direction of the one camera is aligned with a top of the cover.