光谱学与光谱分析 |
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Imaging Spectrometry Radiometric Cross-Calibration Based on Precise Spectral Response Matching |
ZHOU Guan-hua1,2, JIANG He1,2, ZHAO Hui-jie1,2*, JIA Fei1,2 |
1. School of Instrument Science and Opto-electron Engineering, Beihang University, Beijing 100191, China 2. Key Laboratory of Precision Opto-mechatronics Technology, Ministry of Education, Beihang University, Beijing 100191, China |
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Abstract The present research describes the development of an improved cross-calibration method of on-orbit satellite sensor. The EO-1/Hyperion was taken as the referenced sensor and HJ-1A/HSI was taken as the uncalibrated sensor. The differences between the bands configurations were removed by the precise spectral response matching using the deconvolution method, which significantly reduced the radiometric calibration uncertainty of HSI sensor. The calibration coefficients of HSI for all 115 bands were acquired. The uncertainties of calibration coefficient from band 1 to band 60 stably lie in 5%~8%, and for all the other bands excerpt for the oxygen absorption which lies in at 760 nm and the water vapor absorption which lies in at 940 nm, the uncertainties of calibration coefficients are changed from 7% to 18%, which increased as the wavelength increased. Contrasted Compared with the traditional spectral matching method, the method proposed can improve the calibration accuracy by about 50%, which can meet the demand of the quantitive application for hyperspectral remote sensing data. It demonstrated the good precision and reliability of the method. It solved the spectral matching problem when the band configuration is big enough so that the cross calibration accuracy is too low and is difficult to apply in hyperspectral sensor cross-calibration, and provides a new method to frequently update the calibration coefficients for hyperspectral imager.
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Received: 2012-05-15
Accepted: 2012-08-08
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Corresponding Authors:
ZHAO Hui-jie
E-mail: hjzhao@buaa.edu.cn
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[1] WGCV Newsletter Issue 10. http: //www.wgcvceos.org/docs/newsletters/wgcv_newsletter_issue10.pdf,2003. [2] Biggar Stuart F. Transactions on Geoscience and Remote Sensing, 2003, 41(6): 1174. [3] Knight E J. Polarization Effects in the Radiometric Calibration of Earth Remote Sensing Satellites. The University of Arizona, 2000. [4] XU Bo-ming(徐博明). Payload Technology of Meteorological Satellite(气象卫星有效载荷技术). Beijing: China Astronautic Publishing House(北京:中国宇航出版社),2005. 273. [5] CHEN Zheng-chao, LIU Xiang, LI Jun-sheng,et al(陈正超, 刘 翔, 李俊生, 等). Journal of Astronautics(宇航学报),2008, 29(2): 638. [6] Zhao Huijie, Jia Guorui, Li Na. IEEE Transactions on Geoscience and Remote Sensing,2010, 48(11): 3903. [7] Gunar S G,Perarlman J S, Mendenhall J A, et al. IEEE Transactions on Geoscience and Remote Sensing, 2003, 41(6): 1149. |
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