A geometric and radiometric calibration and test apparatus for electro-optical thermal-IR (8-12 micron) instruments and designed to simulate angularly-extending thermal-IR sources with different geometries and with thermal-IR emissions containing hot-cold transitions. The apparatus comprises an IR collimator having an optical axis and a focal plane; a thermal-IR source movable relative to the collimator to be controllably arrangeable and displaceable in the focal plane of the collimator, and operable to radiate thermal-IR radiations towards the collimator; and a kit of masks interchangeably arrangeable in front of the thermal-IR source and having geometric and radiometric properties to cause the thermal-IR radiation reproduced on the electro-optical instrument to be calibrated or tested to contain different hot-cold transitions.

Provided is a method of calibrating a microwave radiometer, which eliminates use of liquid nitrogen as a calibration source. The method is applied to a microwave radiometer configured to receive, by a receiver having a primary radiator connected thereto, a radio wave emitted from an object to be measured depending on a temperature of the object to be measured and to measure a brightness temperature of the object to be measured from an output signal of the receiver. In the method, the method a noise temperature T.sub.rx of the receiver appearing on an output side of the receiver is calibrated by observing a plurality of calibration sources having known brightness temperatures. The method includes using a radio wave reflector configured to totally reflect noise radiated from an input side of the receiver as one of the plurality of calibration sources.

A calibration method for a temperature measurement device, the method including: measuring dispersed spectrum information of radiation energy from a black body furnace and dark current data with a first temperature measurement device and with a second temperature measurement device that is to be swapped with the first temperature measurement device, at each of a plurality of different temperatures; generating, using information thus measured, a second temperature measurement value to be measured by a second contact thermometer included in the second temperature measurement device, and a second dispersed spectrum information corresponding to the second temperature measurement value, from a first temperature measurement value measured by a first contact thermometer included in the first temperature measurement device and a first dispersed spectrum information corresponding to the first temperature measurement value; and determining, using the information thus generated, the basis spectrum and the calibration line for the second temperature measurement device.

The present invention relates to a blackbody radiation source. The blackbody radiation source comprises a blackbody radiation cavity and a carbon nanotube structure. The blackbody radiation cavity comprises an inner surface. The carbon nanotube structure is located on the inner surface. The carbon nanotube structure comprises a first carbon nanotube layer in contact with the inner surface, a second carbon nanotube layer located on a surface of the first carbon nanotube layer and a third carbon nanotube layer located between the first carbon nanotube layer and the second carbon nanotube layer. The first carbon nanotube layer and the second carbon nanotube layer are fixed together by the third carbon nanotube layer.

A temperature measurement method includes obtaining a target temperature of a to-be-measured region based on a temperature measurement model and an obtained infrared image of the to-be-measured region; and outputting the target temperature, where the temperature measurement model is a temperature measurement model obtained by training a neural network based on an infrared image of a black body and an infrared image of a preset region.

An ultra-small thermal imaging core, or micro-core. The design of the micro-core may include substrates for mounting optics and electronic connectors that are thermally matched to the imaging Focal Plane Array (FPA). Test fixtures for test and adjustment that allow for operation and image acquisition of multiple cores may also be provided. Tooling may be included to position the optics to set the core focus, either by moving the lens and lens holder as one or by pushing and/or pulling the lens against a lens positioning element within the lens holder, while observing a scene. Test procedures and fixtures that allow for full temperature calibration of each individual core, as well as providing data useful for uniformity correction during operation may also be included as part of the test and manufacture of the core.

A method and device are provided access control of persons. The method includes: detecting by sensor a reference radiation in the infrared, IR, wavelength range using an IR image sensor; and calibrating the IR image sensor as a temperature sensor in relation to the acquired reference radiation used as a standard at the reference temperature. The method also includes acquiring by image sensor at least an area section of a body surface of a person to be controlled and generating thermal image data representing the thermal image of the area section acquired; determining a body temperature of the person; and allowing or denying access of the person to an access-restricted spatial area based on the determined body temperature.

A method and device are provided access control of persons. The method includes: detecting by sensor a reference radiation in the infrared, IR, wavelength range using an IR image sensor; and calibrating the IR image sensor as a temperature sensor in relation to the acquired reference radiation used as a standard at the reference temperature. The method also includes acquiring by image sensor at least an area section of a body surface of a person to be controlled and generating thermal image data representing the thermal image of the area section acquired; determining a body temperature of the person; and allowing or denying access of the person to an access-restricted spatial area based on the determined body temperature.

A system simulates hyperspectral imaging data or multispectral imaging data for a simulated sensor. Blackbody radiance of real-world thermal imagery data is computed using a Planck function, which generates a simulated spectral hypercube. Spectral emissivity data for background materials are multiplied by a per-pixel weighting function, which generates weighted spectral emissivity data. The simulated spectral hypercube is multiplied by the weighted spectral emissivity data, which generates background data in the simulated spectral hypercube. Simulated targets are inserted the background data using the Planck function. The simulated spectral hypercube is modified, and then it is used to estimate a mission measure of effectiveness of the simulated sensor.

An apparatus for automobile vehicle rotor temperature measurement includes a motor having a rotor. A stator has the rotor positioned within the stator. An aperture extends through the stator. A sensor is positioned in alignment with the aperture sensing a temperature of at least a surface of the rotor.