A computer-implemented method for displaying thermal images by a thermal imager device is provided. The method includes displaying, by a user interface of a computing device, a plurality of thermal images corresponding to a respective plurality of objects in a scene captured by the thermal imager device. The plurality of thermal images are displayed by a first representation scheme based on a first thermal scale comprising a first range of temperature values corresponding to the plurality of objects. The method includes receiving, by the computing device, a user selection of a subplurality of the plurality of thermal images. And the method includes, responsive to the user selection, displaying, by the user interface, the subplurality of the plurality of thermal images by a second representation scheme based on a second thermal scale comprising a second range of temperature values corresponding to a respective subplurality of the plurality of objects.

A thermal imaging sensor may include: a pixel array in which pixels with microbolometers are arranged in an MN matrix, where M and N are integers greater than or equal to 2; a row controller configured to output a row control signal through one or more row control signal lines to select and control a predetermined row from among multiple rows; switches connected to the one or more row control signal lines and disposed at each pixel; and a plurality of column integrators configured to read a current signal from the pixel array obtained through a pixel output line and convert it into a voltage signal.

A thermal imaging sensor may include: a pixel array in which pixels with microbolometers are arranged in an MN matrix, where M and N are integers greater than or equal to 2; a row controller configured to output a row control signal through one or more row control signal lines to select and control a predetermined row from among multiple rows; switches connected to the one or more row control signal lines and disposed at each pixel; and a plurality of column integrators configured to read a current signal from the pixel array obtained through a pixel output line and convert it into a voltage signal.

Various embodiments disclosed herein describe a divided-aperture infrared spectral imaging (DAISI) system that is adapted to acquire multiple IR images of a scene with a single-shot (also referred to as a snapshot). The plurality of acquired images having different wavelength compositions that are obtained generally simultaneously. The system includes at least two optical channels that are spatially and spectrally different from one another. Each of the at least two optical channels are configured to transfer IR radiation incident on the optical system towards an optical FPA unit comprising at least two detector arrays disposed in the focal plane of two corresponding focusing lenses. The system further comprises at least one temperature reference source or surface that is used to dynamically calibrate the two detector arrays and compensate for a temperature difference between the two detector arrays.

Various embodiments disclosed herein describe a divided-aperture infrared spectral imaging (DAISI) system that is adapted to acquire multiple IR images of a scene with a single-shot (also referred to as a snapshot). The plurality of acquired images having different wavelength compositions that are obtained generally simultaneously. The system includes at least two optical channels that are spatially and spectrally different from one another. Each of the at least two optical channels are configured to transfer IR radiation incident on the optical system towards an optical FPA unit comprising at least two detector arrays disposed in the focal plane of two corresponding focusing lenses. The system further comprises at least one temperature reference source or surface that is used to dynamically calibrate the two detector arrays and compensate for a temperature difference between the two detector arrays.

Provided here are: an infrared imaging element that receives infrared light to capture a thermal image; an element temperature sensor that detects a temperature of the infrared imaging element; an FPN memory that stores therein FPN data at each of the temperatures; a frame memory that saves a plurality of pieces of frame data composed of thermal images captured by the infrared imaging element in a fixed period of time; and an FPN data generation unit that, when an imaging target is determined not to have changed on the basis of the frame data, acquires from the FPN memory, the FPN data corresponding to the temperature of the infrared imaging element at which said frame data were obtained; and performs averaging processing between average values AF of the plurality of pieces of frame data and the thus-acquired FPN data, to thereby regenerate the FPN data in an updated manner.

Provided here are: an infrared imaging element that receives infrared light to capture a thermal image; an element temperature sensor that detects a temperature of the infrared imaging element; an FPN memory that stores therein FPN data at each of the temperatures; a frame memory that saves a plurality of pieces of frame data composed of thermal images captured by the infrared imaging element in a fixed period of time; and an FPN data generation unit that, when an imaging target is determined not to have changed on the basis of the frame data, acquires from the FPN memory, the FPN data corresponding to the temperature of the infrared imaging element at which said frame data were obtained; and performs averaging processing between average values AF of the plurality of pieces of frame data and the thus-acquired FPN data, to thereby regenerate the FPN data in an updated manner.

The present invention relates to a photothermal effect-based mid-infrared detecting apparatus including an optical sensor that detects visible light, an infrared light layer disposed on the optical sensor and including a material that absorbs a mid-infrared light, and a processor that detects the mid-infrared light by analyzing a sensor signal output from the optical sensor, wherein the optical sensor receives heat generated by the mid-infrared light incident on the infrared light layer and outputs the sensor signal modulated by the heat to the processor.

The present invention relates to a photothermal effect-based mid-infrared detecting apparatus including an optical sensor that detects visible light, an infrared light layer disposed on the optical sensor and including a material that absorbs a mid-infrared light, and a processor that detects the mid-infrared light by analyzing a sensor signal output from the optical sensor, wherein the optical sensor receives heat generated by the mid-infrared light incident on the infrared light layer and outputs the sensor signal modulated by the heat to the processor.

Deformable sensors having a stereo depth sensor and an infrared sensor and methods of their use are disclosed. In one embodiment, a deformable sensor includes an enclosure having a housing and a deformable membrane, wherein the deformable membrane is transparent to a wavelength band in the infrared spectrum, a stereo depth sensor that is disposed within the enclosure and is configured to view an underside of the deformable membrane, and output a deformation region of the deformable membrane as a result of contact with an object, wherein the deformation region includes depth information, and an infrared sensor that is disposed within the enclosure and is configured to view the object through the deformable membrane when the object contacts the deformable membrane and output a contact patch region corresponding with a region of the deformable membrane that contacts the object.