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Target Recognition and Accuracy Evaluation of Infrared Radiation Characteristics Measurement Equipment in Dynamic Environment

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DOI: 10.23977/jeis.2023.080110 | Downloads: 16 | Views: 244


Wei Ai 1, Yuan Chong 1, Yukun Wang 1


1 Unit 91550 of PLA, Dalian, Liaoning, China

Corresponding Author

Wei Ai


Infrared radiation characteristic measurement is an important means to obtain information such as target radiation brightness, temperature, and radiation intensity. The measured results can be used to detect and identify targets, and evaluate target stealth effects and other aspects. However, the measurement of infrared radiation characteristics is easily affected by dynamic environments, and it is often difficult to ensure the accuracy of the measured data of infrared radiation characteristics in dynamic environments. Therefore, this article began to study the target recognition and accuracy analysis of infrared radiation characteristics measurement equipment in dynamic environments, testing the calibration results of the medium wave infrared radiation measurement system under different integration times, and the imaging uniformity of the target surface in static and dynamic environments. In the experiment, the imaging uniformity of the target surface in static environments was between 0.9 and 1.1, while the imaging uniformity of the target surface in dynamic environments was between 0.7 and 1.6. The lower the uniformity of target imaging, the smaller the accuracy of infrared radiation measurement. Therefore, dynamic environments can affect the accuracy of infrared radiation measurement.


Infrared Radiation Characteristics, Dynamic Environment, Target Recognition, Accuracy Analysis


Wei Ai, Yuan Chong, Yukun Wang, Target Recognition and Accuracy Evaluation of Infrared Radiation Characteristics Measurement Equipment in Dynamic Environment. Journal of Electronics and Information Science (2023) Vol. 8: 76-83. DOI:


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