Systems and methods for thermal radiation detection utilizing a thermal radiation detection system are provided. The thermal radiation detection system includes one or more mercury-cadmium-telluride (HgCdTe)-based photodiode infrared detectors or Indium Arsenide (InAr)-based photodiode infrared detectors and a temperature sensing circuit. The temperature sensing circuit is configured to generate signals correlated to the temperatures of one or more of the plurality of infrared sensor elements. The thermal radiation detection system also includes a signal processing circuit.

Improved techniques for infrared imaging and gas detection are provided. In one example, a system includes a sensor array configured to receive infrared radiation from a scene comprising a background portion and a gas. The sensor array includes a first set of infrared sensors configured with a first spectral response corresponding to a first wavelength range of the infrared radiation associated with the background portion. The sensor array also includes a second set of infrared sensors configured with a second spectral response corresponding to a second wavelength range of the infrared radiation associated with the gas. The system also includes a read out integrated circuit (ROIC) configured to provide pixel values for first and second images captured by the first and second sets of infrared sensors, respectively, in response to the received infrared radiation. Additional systems and methods are also provided.

Various methods and devices for ultrasensitive infrared photodetection, infrared imaging, and other optoelectronic applications using the plasmon assisted thermoelectric effect in graphene are described. Infrared detection by the photo-thermoelectric uses the generation of a temperature gradient (ΔT) for the efficient collection of the generated hot-carriers. An asymmetric plasmon-induced hot-carrier Seebeck photodetection scheme at room temperature exhibits a remarkable responsivity along with an ultrafast response in the technologically relevant 8-12 μm band. This is achieved by engineering the asymmetric electronic environment of the generated hot carriers on chemical vapor deposition (CVD) grown large area nanopatterned monolayer graphene, which leads to a record ΔT across the device terminals thereby enhancing the photo-thermoelectric voltage beyond the theoretical limit for graphene. The results provide a strategy for uncooled, tunable, multispectral infrared detection.

Improved techniques for infrared imaging and gas detection are provided. In one example, a system includes a sensor array configured to receive infrared radiation from a scene comprising a background portion and a gas. The sensor array includes a first set of infrared sensors configured with a first spectral response corresponding to a first wavelength range of the infrared radiation associated with the background portion. The sensor array also includes a second set of infrared sensors configured with a second spectral response corresponding to a second wavelength range of the infrared radiation associated with the gas. The system also includes a read out integrated circuit (ROIC) configured to provide pixel values for first and second images captured by the first and second sets of infrared sensors, respectively, in response to the received infrared radiation. Additional systems and methods are also provided.

An imaging device may include an RF source configured to irradiate an object with RF radiation, and an array of RE antenna elements. Each RF antenna element may include a loop bolometer configured to receive the RF radiation after interaction with the object. The imaging device may include a processor configured to generate an image based upon respective outputs from the array of RF antenna elements, and a display coupled to the processor and configured to display the image of the object.

The present application discloses a smart device comprising a temperature sensor, and a method for controlling the same. The present application relates to a smart device comprising a temperature sensor for measuring the temperature of a certain object at a position spaced a certain distance from the object and having a measurement range varying according to the distance from the object. The present application provides a method for controlling a smart device comprising the steps of: measuring a distance from the smart device to the object for measuring the temperature of the object; if the measurement range of the temperature sensor at the measured position is not placed within the object, notifying a user that the temperature of the object cannot be measured; and directing the user to place the measurement range within the object.

An image sensor includes on a support a plurality of first pixels and a plurality of second pixels intended to detect an infrared radiation emitted by an element of a scene. Each of the pixels includes a bolometric membrane suspended above a reflector covering the support, wherein the reflector of each of the first pixels is covered with a first dielectric layer, and the reflector of each of the second pixels is covered with a second dielectric layer differing from the first dielectric layer by its optical properties.

An imaging device may include an RF source configured to irradiate an object with RF radiation, and an array of RE antenna elements. Each RF antenna element may include a loop bolometer configured to receive the RF radiation after interaction with the object. The imaging device may include a processor configured to generate an image based upon respective outputs from the array of RF antenna elements, and a display coupled to the processor and configured to display the image of the object.

An infrared sensor includes a supporting body having supporting body metal wiring that allows infrared rays to pass through. The supporting body is provided so as to cover one portion of an infrared detecting portion in a different plane spatially separated from that of the infrared detecting portion. The supporting body metal wiring disposed in an interior of the supporting body is such that one portion of a cobalt iron film is oxidized by a plasma discharge being carried out in an oxygen atmosphere. According to this kind of structure, infrared rays pass through the supporting body, and are absorbed by the infrared detecting portion, because of which there is no need to provide an infrared absorption layer in an upper layer of the supporting body.

The present application discloses a smart device comprising a temperature sensor, and a method for controlling the same. The present application relates to a smart device comprising a temperature sensor for measuring the temperature of a certain object at a position spaced a certain distance from the object and having a measurement range varying according to the distance from the object. The present application provides a method for controlling a smart device comprising the steps of: measuring a distance from the smart device to the object for measuring the temperature of the object; if the measurement range of the temperature sensor at the measured position is not placed within the object, notifying a user that the temperature of the object cannot be measured; and directing the user to place the measurement range within the object.