A temperature abnormality detection device includes a plurality of infrared temperature sensors respectively capable of detecting temperature in a different detection area of an equipment, and a device body including a temperature abnormality determination unit that determines that the temperature in the detection area detected by each of the plurality of infrared temperature sensors is abnormal when the temperature in the detection area is higher than a reference temperature. The plurality of infrared temperature sensors is connected to each other by crossover wiring.

A sensor installed into a mold including a cable insertion member having a fixing portion with a fitting recess is provided. The sensor includes an optical fiber a part of which is bendable, and a fiber holder having a fiber insertion portion through which the optical fiber is inserted and a to-be-fixed portion extending from the fiber insertion portion. Further, the to-be-fixed portion is fixed to the fixing portion while being fitted to the fitting recess.

A temperature sensing module includes a hollow base, an infrared temperature sensor, and a condenser lens. The hollow base has a through hole, a first end, and a second end opposite to the first end. The first end has a first opening, the second end has a second end, and the through hole is in communication between the first opening and the second opening. The infrared temperature sensor is disposed in the through hole and adjacent to the second opening. The infrared temperature sensor includes a photosensitive surface, and the photosensitive surface faces the first opening. The condenser lens is disposed in the through hole and adjacent to the first opening. The condenser lens corresponds to the photosensitive surface of the infrared temperature sensor. An electronic device having the temperature sensing module is also provided.

The disclosed MMW wave sensing camera calibration arrangement that generally includes a millimeter wave camera that uses an energy emission calibration panel as a calibration standard. The MMW camera is positioned opposite the calibration panel in the MMW camera's field-of-view. The calibration panel is held at a constant temperature to provide a standard emission of millimeter waves that is sensed by an MMW sensor to set or otherwise calibrate the MMW camera to a baseline emissivity value corresponding to the panel. The MMW camera is linked to a microprocessor and non-transient computer memory containing a calibration routine that is configured to reset the baseline only when nothing obstructs the calibration panel's field-of-view. A visual display is linked to the MMW camera and configured to display an MMW signature of a metal object that is disposed on a person's body when the person's body is in the field-of-view, the metal object concealed by clothing worn over the person's body.

A pest deterrent system is provided. The pest deterrent system includes a sensor module and an actuator module. The sensor module includes a first housing, a sensor, and a controller. The sensor is positioned within the first housing and proximate to the view window such that the sensor is in visual communication with the view window and configured to detect objects outside of the first housing. The controller is positioned within the first housing and is operatively coupled to the sensor. The controller is configured to receive a signal from the sensor, such as an alert that an object is near the sensor module. The actuator module includes a second housing separate from the first housing, an actuator, and a second controller. The second controller configured to receive a signal from the first controller to actuate the actuator in response to the sensor being triggered.

A method for manufacturing a near-infrared sensor cover includes arranging a mask in a region of an undercoating layer formed on a rear surface of a base, the region being different from a heater formation region in which a heater is to be formed and different from a belt-shaped separation region extending along an edge of the heater formation region, forming a heat-generating film on the mask and the undercoating layer, the heat-generating film being made of the conductive heat-generating material, peeling, using a laser, the heat-generating film formed in the separation region, and removing the mask and the heat-generating film formed on the mask. The separation region has a width that is set to be smaller than a beam diameter of each of near-infrared rays transmitted from the transmitting portion.

A cooled infrared camera includes a window housing comprising a plate having an opening, a window positioned in the opening of the plate, a first sidewall having a first end connected to the plate, a first flange connected to a second end of the first sidewall such that the first sidewall is between the plate and the first flange, a first explosively welded joint between the plate and the first sidewall, and a second explosively welded joint between the first sidewall and the first flange. A header is connected to the first flange of the window housing, and a warm end is connected to the header. The cooled infrared camera further includes a hermetically sealed chamber within the window housing and the header.

This patent specification relates to various smart-home systems. Such a system may include a battery-powered smart home device that communicates using a first wireless protocol characterized by relatively low power usage and relatively low data rates. Such a system may further include a smart wall outlet device. The smart wall outlet device may include wireless communication circuitry comprising a first wireless interface and a second wireless interface. The first wireless interface may be configured to communicate with the battery-powered smart home device using the first wireless protocol. The second wireless interface may be configured to serve as a communication bridge between the battery-powered smart home device and a wireless network that uses a second communication protocol characterized by relatively higher power usage and relatively higher data rates.

This application is directed to a home monitoring and control system including a doorbell installed at a door of a home. The doorbell has a button configured to, upon being touched, depressed or activated, wirelessly initiate a first communication to indicate presence of a person at the door. The doorbell also has a camera configured to capture video data within a field of view, and a processor configured to cause a communication component to enable the first communication and wirelessly stream via a remote server the video data captured by the camera to a monitoring device associated with an occupant of the home. A rechargeable battery is coupled to a housing wire and configured to be charged via the housing wire, and the doorbell is configured to charge and discharge the rechargeable battery based on power usage of the doorbell.

A getter assembly is provided and includes a first canister, an internal can including getter, and a second canister. The internal can is disposable in the first canister to occupy a first position at which the getter is hermetically sealable and second positions at which the getter is exposed to an exterior environment. The second canister is engageable with the first canister to drive movements of the internal can between the first position and the second positions following activation and hermetic sealing of the getter