An atmosphere of ammonia that absorbs infrared light in a wavelength band overlapping with the measurement wavelength band of a radiation thermometer is formed in a chamber in which a semiconductor wafer is thermally treated. A filter that selectively transmits infrared light having a wavelength not overlapping with the absorption wavelength band of ammonia is installed between an optical lens system and a detector of the radiation thermometer to avoid influence of the infrared light absorption by ammonia. A conversion table corresponding to the installed filter is selected from a plurality of conversion tables representing a correlation between energy of infrared light incident on the radiation thermometer and temperature of a black body, and is used at the radiation thermometer. Accordingly, the temperature of the semiconductor wafer can be accurately measured in the atmosphere of ammonia.

The invention discloses a method which analyzes regression coefficient and spectral consistency in the determination of the accuracy of a calibration for a radiometer. The invention's method simulates the output of a total power radiometer and quantifies the calibration accuracy under various atmospheric conditions.

An omnidirectional measurement system for a time-varying characteristic of atmospheric vapor radiation includes an antenna and calibrator assembly, a receiver assembly, a room temperature IF assembly, and a data acquisition and system control assembly. Atmospheric vapor features a wide profile and strong radiation in a frequency band of 183 GHz, and is often seen in the characteristic measurement of atmospheric vapor in high-altitude areas. The omnidirectional measurement system combines a superconductor-insulator-superconductor (SIS) mixer with high detection sensitivity in the frequency band of 183 GHz with a structure that integrates pitch scanning, omnidirectional scanning, and automatic calibration to achieve fast and high-precision omnidirectional scanning measurement of the time-varying characteristic of atmospheric vapor radiation. The omnidirectional measurement system has a pitch adjustment-based fast omnidirectional scanning function, and can measure the time-varying characteristic of atmospheric vapor radiation with higher precision and higher temporal resolution through the SIS mixer with higher sensitivity.

An omnidirectional measurement system for a time-varying characteristic of atmospheric vapor radiation includes an antenna and calibrator assembly, a receiver assembly, a room temperature IF assembly, and a data acquisition and system control assembly. Atmospheric vapor features a wide profile and strong radiation in a frequency band of 183 GHz, and is often seen in the characteristic measurement of atmospheric vapor in high-altitude areas. The omnidirectional measurement system combines a superconductor-insulator-superconductor (SIS) mixer with high detection sensitivity in the frequency band of 183 GHz with a structure that integrates pitch scanning, omnidirectional scanning, and automatic calibration to achieve fast and high-precision omnidirectional scanning measurement of the time-varying characteristic of atmospheric vapor radiation. The omnidirectional measurement system has a pitch adjustment-based fast omnidirectional scanning function, and can measure the time-varying characteristic of atmospheric vapor radiation with higher precision and higher temporal resolution through the SIS mixer with higher sensitivity.

A detection apparatus includes an acquisition unit and a detector. The acquisition unit acquires temperatures respectively corresponding to multiple parts of a subject identified from a visible image from a temperature image in which the temperatures of the parts of the subject are visualized. The detector detects a part not included in a temperature range preset for each of the parts, the part being included in the multiple parts of the subject whose temperatures are acquired by the acquisition unit.

The invention provides a method for detecting thermal emissions from the new moon, wherein the new moon is positioned at an angle of less than about 5 degrees from the Sun. The invention utilizes a radio telescope, wherein a side-lobe level of the radio telescope is less than about 20 dB, wherein an effective telescope diameter of the radio telescope depends on a wavelength of operation. Further, a FWHM beamwidth of the radio telescope is less than about 0.5 degree. The method comprises setting one or more of the operating frequency of the radio telescope to a value selected from the range of about 1 GHz and about 100 GHz, and the operating bandwidth of the radio telescope to a value selected from the range of about 1 GHz and about 10 GHz. In addition, the method comprises collecting at least one observation from the radio telescope.

A method for measuring furnace temperatures. The method includes obtaining radiance measurements from a plurality of regions of interest (ROIs) using a plurality of thermal imaging cameras, and measuring a surface temperature using a radiance measurement obtained from an ROI selected from the plurality of ROIs. Measuring the surface temperature includes determining an effective background radiance affecting the selected ROI using radiance measurements obtained from ROIs different from the selected ROI, obtaining a compensated radiance by removing the effective background radiance from the radiance measurement obtained from the selected ROI, and converting the compensated radiance to the measured surface temperature.

A system and method are provided for observing conditions in an environment around a transportation vehicle and adjusting operation of the transportation vehicle in response to the observed conditions. The temperatures of features in the environment can be determined to compensate for varying conditions in the environment in operating the transportation vehicle.

A method for measuring furnace temperatures. The method includes obtaining radiance measurements from a plurality of regions of interest (ROIs) using a plurality of thermal imaging cameras, and measuring a surface temperature using a radiance measurement obtained from an ROI selected from the plurality of ROIs. Measuring the surface temperature includes determining an effective background radiance affecting the selected ROI using radiance measurements obtained from ROIs different from the selected ROI, obtaining a compensated radiance by removing the effective background radiance from the radiance measurement obtained from the selected ROI, and converting the compensated radiance to the measured surface temperature.

Techniques for atmospheric absorption determination using embedded sensor data are provided. In one example, a system includes a housing. The system further includes a sensing device within the housing. The sensing device is configured to determine a humidity within the housing and a temperature within the housing. The system further includes a logic device. The logic device is configured to compensate the humidity and the temperature based on a location of the sensing device within the housing relative to heat sources within the housing. The logic device is further configured to determine a moisture value based on compensation of the humidity and the temperature. The logic device is further configured to determine an atmospheric absorption value based on the moisture value. Related devices and methods are also provided.