Sensors (Mar 2024)

Temperature-Automated Calibration Methods for a Large-Area Blackbody Radiation Source

  • Wenhang Yang,
  • Chen Cao,
  • Pujiang Huang,
  • Jindong Bai,
  • Bangjian Zhao,
  • Shouzheng Zhu,
  • Haijun Jin,
  • Ke Jin,
  • Xin He,
  • Chunlai Li,
  • Jianyu Wang,
  • Shijie Liu,
  • Hongxing Qi

DOI
https://doi.org/10.3390/s24051707
Journal volume & issue
Vol. 24, no. 5
p. 1707

Abstract

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High-precision temperature control of large-area blackbodies has a pivotal role in temperature calibration and thermal imaging correction. Meanwhile, it is necessary to correct the temperature difference between the radiating (surface of use) and back surfaces (where the temperature sensor is installed) of the blackbody during the testing phase. Moreover, large-area blackbodies are usually composed of multiple temperature control channels, and manual correction in this scenario is error-prone and inefficient. At present, there is no method that can achieve temperature-automated calibration for a large-area blackbody radiation source. Therefore, this article is dedicated to achieving temperature-automated calibration for a large-area blackbody radiation source. First, utilizing two calibrated infrared thermometers, the optimal temperature measurement location was determined using a focusing algorithm. Then, a three-axis movement system was used to obtain the true temperature at the same measurement location on a large-area blackbody surface from different channels. This temperature was subtracted from the blackbody’s back surface. The temperature difference was calculated employing a weighted algorithm to derive the parameters for calibration. Finally, regarding experimental verification, the consistency error of the temperature measurement point was reduced by 85.4%, the temperature uniformity of the surface source was improved by 40.4%, and the average temperature measurement deviation decreased by 43.8%. In addition, this system demonstrated the characteristics of strong environmental adaptability that was able to perform temperature calibration under the working conditions of a blackbody surface temperature from 100 K to 573 K, which decreased the calibration time by 9.82 times.

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