ANARC: Active Light Source for Nighttime Absolute Radiometric Calibration

The optical components of space-borne sensors are subject to environmental degradation, resulting in changing response characteristics, especially at different wavelengths. Consequently, the implementation of radiometric calibration is imperative to ensure the accuracy and reliability of the sensors...

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Published inIEEE geoscience and remote sensing letters Vol. 21; pp. 1 - 5
Main Authors Qiu, Yanqian, Zhao, Bing, Zhou, Yifan, Yi, Yang, Wang, Kainan, Yin, Zhenping, Zhao, Lei, Muller, Detlef, Wang, Xuan, Hu, Xiuqing
Format Journal Article
LanguageEnglish
Published Piscataway IEEE 2024
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Accuracy
Atmospheric measurements
Atmospheric transmittance
Atmospheric waves
Calibration
Emissivity
Environmental degradation
Excitation spectra
High gain
Imaging radiometers
Infrared imaging
Infrared radiometers
Laser radar
Lidar
Light sources
Luminous intensity
Monochromatic light source
multiwavelengths
Night
Night-time
Nighttime
Optical components
Photodegradation
Radiometers
radiometric calibration
Radiometry
Satellite broadcasting
Satellites
Sensors
spectral response
Unmanned aerial vehicles
Wavelengths
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Summary:The optical components of space-borne sensors are subject to environmental degradation, resulting in changing response characteristics, especially at different wavelengths. Consequently, the implementation of radiometric calibration is imperative to ensure the accuracy and reliability of the sensors. Calibration requires the capability to provide known excitations across the sensor's spectral range, which is difficult to achieve with the existing means. Thus, this letter proposes a ground-based multiwavelengths active light source for nighttime absolute radiometric calibration (ANARC), capable of generating light with a uniform intensity distribution, three monochromatic wavelengths, and variable intensity within the satellite detection field of view. The absolute intensity of ANARC is precalibrated by an unmanned aerial vehicle (UAV) equipped with an optical power meter. The atmospheric transmittance during satellite overpasses is measured by co-located lidar systems. We conducted two test experiments targeting the NOAA-20 satellite. The deviations of the top-of-atmosphere (TOA) ANARC emissivity from the measured emissivity from the Visible/Infrared Imaging Radiometer Suite Day Night Band were −8.06% and 1.02%, respectively. At the same time, ANARC can cover the dynamic range of the high gain stage in the low light band (LLB) of the moderate resolution spectral imager-low light (MERSI-LL) in FengYun-3 E. This preliminary verification suggests the feasibility of using ANARC for nighttime sensor calibration, which provides a new opportunity to improve radiometric calibration accuracy. It could also facilitate hyperspectral sensor calibration due to three monochromatic wavelengths of ANARC.
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ISSN:1545-598X
1558-0571
DOI:10.1109/LGRS.2024.3436005