Systems and methods are provided for filtering coherent infrared light from a thermal background for protection of infrared (IR) imaging arrays and detection systems. A Michelson interferometer is used for coherent light filtering. In an implementation, a system includes a fixed mirror, a beam splitter, and a moving mirror which can be controlled translationally, as well as tip/tilt. The Michelson interferometer may be used as an imaging system. For imaging applications, a system may comprise a tunable array of micro-electromechanical systems (MEMS) mirrors. A mid-wave IR interferometer with electronic feedback and MEMS mirror array is provided.

A film structural component is supported by a substrate. The film structural component includes a plurality of thermal infrared detectors arranged in an array. Each of the plurality of thermal infrared detectors includes a thermopile having a plurality of hot junctions and a plurality of cold junctions. An infrared sensor further includes a plurality of heaters and at least one thermometer. The plurality of heaters are provided on the first principal surface of the substrate. The at least one thermometer is provided on the first principal surface of the substrate and is configured to detect a temperature of the substrate. Each of the plurality of heaters faces another heater of the plurality of heaters via a region including the plurality of thermal infrared detectors in plan view in the thickness direction of the substrate.

A thermal imaging apparatus comprising: a thermal detector device (100) comprising an array of thermal sensing pixels (102) and signal processing circuitry (104) coupled to the detector device (100). The circuitry (104) supports a background identifier (110) and a pixel classifier (112), the background identifier (110) comprising a common intensity identifier (114) and an expected background intensity calculator (116). The background identifier (110) receives pixel measurement data captured by the detector device (100) in respect of pixels of the array (102) and the common intensity identifier (114) identifies a largest number of substantially the same pixel intensity values from the pixel measurement data. The expected background intensity calculator (116) uses the largest number of substantially the same pixel intensity values to generate a model of expected background intensity levels. The pixel classifier (112) uses the model to determine whether an intensity measurement by a pixel (118) of the array (102) corresponds to a background or an object in an image.

One or more temperature measuring devices are described that comprise; thermal imaging cameras capable of detection and provision of an exact location of at least one created dynamic image scanned by and triangulated with at least two thermal imaging cameras, and a gate that provides a constrained targeted pathway through which at least one person must travel so that dynamic thermal data of the person is captured as the person is moving through the gate and wherein thermal imaging cameras are geometrically arranged in positions such that the thermal imaging cameras field of view exist on or within the gate and wherein the person is scanned and provides targeted dynamic thermal data that is converted into one or more temperature readings that measure and transmit the temperature readings from one or more photodetectors that sense thermal radiation naturally emitted by people passing through.

A detector locator system comprising: an electromagnetic radiation (EMR) source array comprising a plurality of EMR sources; a detector apparatus comprising an EMR detector configured to detect an EMR signal emitted by the EMR sources, a wireless transceiver configured to transmit an ON signal responsive to the EMR detector receiving the EMR signal; a control unit configured to instruct the driver to control the EMR sources to turn on one at a time in an activation pattern, receive the ON signal, and designate, responsive to the ON signal, the EMR source that triggered the detection signal as a triggering EMR source.

A seamlessly splicing method based on three lenses and area array detectors, includes: imaging a field of view simultaneously using the three lenses; arranging three area array detectors at corresponding focal plane positions of each of the three lenses to obtain imaging images, respectively; and generating a complete seamlessly imaging result of the field of view by pairwise splicing the imaging images obtained from adjacent area array detectors, through staggered splicing of the three lens and/or the area array detectors.

There is provided an auto detection system including a thermal detection device and a host. The host controls an indication device to indicate a prompt message or detection results according to a slope variation of voltage values or 2D distribution of temperature values detected by the thermal detection device, wherein the voltage values include the detected voltage of a single pixel or the sum of detected voltages of multiple pixels of a thermal sensor.

A traction battery for an electrically or semi-electrically driven vehicle. The traction battery includes at least one temperature sensor. The temperature sensor is configured as an infrared sensor and includes a sensor array having several sensor elements for spatially resolved detection of the temperature of a surface of one or more components of the traction battery. A deflection optic is arranged between the respective surface and the sensor array, via which optic the temperature sensor detects the respective surface.

A thermal sensor including a thermal sensing array and a calibration circuit is provided. The thermal sensing array includes a plurality of thermal sensing cells. The thermal sensing cells include a first unmasked thermal sensing cell and a first masked thermal sensing cell. The first unmasked thermal sensing cell senses and obtains a first unmasked sensing data. The first masked thermal sensing cell is disposed adjacent to the first unmasked thermal sensing cell, and the first masked thermal sensing cell obtains a first masked sensing data. The calibration circuit is coupled to the first masked thermal sensing cell and the first unmasked thermal sensing cell. The calibration circuit calibrates the first unmasked sensing data obtained by the first unmasked thermal sensing cell according to the first masked sensing data obtained by the first masked thermal sensing cell to which the first unmasked thermal sensing cell is adjacent.

An apparatus and method for detection of infrared radiation is disclosed. The apparatus includes a detector including a cascaded type II superlattice for detecting infrared radiation. The method includes detecting an infrared radiation signal using a detector that includes n cascading layers comprised of n−1 repeats of a first type II superlattice structure and a tunnel junction, followed by a final (n.sup.th) type II superlattice structure, where n is a whole and positive number.