国产遥感传感器大气层外波段平均太阳光谱辐照度计算

doi:10.3724/SP.J.1047.2014.00621

地球信息科学学报 ›› 2014, Vol. 16 ›› Issue (4): 621-627.doi: 10.3724/SP.J.1047.2014.00621

国产遥感传感器大气层外波段平均太阳光谱辐照度计算

张璐^1,²(), 施润和^1,^2**(), 徐永明³, 李龙^1,², 高炜^1,²

1. 华东师范大学地理信息科学教育部重点实验室,上海 200241
2. 华东师范大学环境遥感与数据同化联合实验室,上海 200241
3. 南京信息工程大学遥感学院,南京 210044

收稿日期:2014-01-13 修回日期:2014-04-03 出版日期:2014-07-10 发布日期:2014-07-10
作者简介:
作者简介：张璐(1991-),女,硕士生,主要从事大气遥感方面研究。E-mail：zl66ahgd@gmail.com
基金资助:
国家自然科学基金项目(41201358);上海市科委重点支撑项目(13231203804)

Calculation of Mean Solar Exoatmospheric Irradiances of Several Sensors Onboard of Chinese Domestic Remote Sensing Satellites

ZHANG Lu^1,²(), SHI Runhe^1,^2*(), XU Yongming³, LI Long^1,², GAO Wei^1,²

1. Key Laboratory of Geographic Information Science, Ministry of Education, East China Normal University, Shanghai 200241, China
2. Joint Laboratory for Environmental Remote Sensing and Data Assimilation, ECNU and CEODE, Shanghai 200241, China
3. Nanjing University of Information Science and Technology, School of Remote Sensing, Nanjing 210044, China

Received:2014-01-13 Revised:2014-04-03 Online:2014-07-10 Published:2014-07-10
About author:
*The author: CHEN Nan, E-mail：fjcn99@163.com

摘要/Abstract

摘要：

目前,我国大部分遥感传感器的大气层外波段平均太阳光谱辐照度(Mean solar exoatmospheric irradiances over band b,简称ESUN_b)尚未公布,这给遥感图像表观反射率的计算带来了不便,在一定程度上影响了数据资料的应用和推广。本文基于已有官方ESUN_b值的EO1/ALI、Terra/ASTER、QuickBird等多种中、高空间分辨率传感器,对9条常见的太阳光谱曲线进行比较分析。结果表明,WRC太阳光谱曲线最合适计算中分辨率传感器的ESUN_b,而Wehrli太阳光谱曲线最合适计算高分辨率传感器的ESUN_b。基于WRC太阳光谱曲线和Wehrli太阳光谱曲线计算,得到了ZY-1 02C/PMS相机、ZY-3/TLC相机和MUX相机,以及GF-1/WFV相机和PMS相机各波段ESUN_b值,并对ESUN_b值的不确定性进行了分析。结果显示,太阳光谱选取的不同,对ESUN_b的取值会产生-1.94%至1.48%的偏差。本文使用多种卫星传感器交叉比较的方式确定了最佳的太阳光谱,给出了ZY-1 02C、ZY-3和GF-1等卫星搭载的遥感传感器各波段的ESUN_b值,为这些国产卫星遥感数据的广泛应用提供便利。此外,本文所用方法简便易行,在其他新的遥感传感器上具有推广应用价值。

关键词: 大气层外波段平均太阳光谱辐照度, 太阳光谱曲线, 资源一号02C(ZY-1 02C), 资源三号, 高分一号

Abstract:

Mean solar exoatmospheric irradiances over band b (ESUN_b) is an important parameter for computing apparent reflectance. In recent years, ZY-1 02C, ZY-3 and GF-1 were launched and they have played an important role in land and resources survey as well as urban planning and construction. However, ESUN_b values of these domestic remote sensing satellites have not been released publicly, and till now it causes difficulties in processing their DN values to the physical quantities. In order to calculate ESUN_b values, Extraterrestrial Solar Spectral Irradiance and Spectral Response Function (SRF) are necessary. This paper aimed to calculate the unknown ESUN_b based on a selection of optimal solar spectrum from nine released solar spectra, including ASTM-E490, WRC, Wehrli, etc. A number of medium spatial resolution and high spatial resolution sensors whose ESUN_b had been officially released were chosen, such as EO1/ALI, Terra/ASTER, QuickBird, etc. Through calculating the mean absolute error (MAE) and the standard deviation of absolute error (SDAE) between the calculated ESUN_b values and the officially released values for these sensors, WRC solar spectrum and Wehrli solar spectrum were selected as the optimal solar spectra for sensors with medium spatial resolution and high spatial resolution respectively. This is because WRC solar spectrum showed the least MAE (3.208 W·m²·μm^-1) and Wehrli solar spectrum showed the least MAE (0.701 W·m²·μm^-1) and SDAE (1.034 W·m²·μm^-1). Based on WRC solar spectrum and Wehrli solar spectrum, ESUN_b values of ZY-1 02C/PMS, ZY-3/Multispectral camera and Three-line array camera, GF-1/WFV and PMS were calculated and given accordingly. The resultant values were between the maximum and minimum ESUN_b values for all the nine solar spectra. In addition, the uncertainty analysis was conducted and their relative biases due to the selection of different solar spectra were between -1.938% and 1.477%. Calculating ESUN_b values in this way is simple and easy, because it can ensure the comparability of data between different remote sensors. This method can be applied to the other new remote sensing sensors so as to fully utilize their data.

Key words: mean solar exoatmospheric irradiances over band b, Exoatmospheric Solar Spectral Irradiance, ZY-1 02C, ZY-3, GF-1

张璐, 施润和, 徐永明, 李龙, 高炜. 国产遥感传感器大气层外波段平均太阳光谱辐照度计算[J]. 地球信息科学学报, 2014, 16(4): 621-627.DOI:10.3724/SP.J.1047.2014.00621

ZHANG Lu,SHI Runhe,XU Yongming,LI Long,GAO Wei. Calculation of Mean Solar Exoatmospheric Irradiances of Several Sensors Onboard of Chinese Domestic Remote Sensing Satellites[J]. Journal of Geo-information Science, 2014, 16(4): 621-627.DOI:10.3724/SP.J.1047.2014.00621

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参考文献 21

[1]	孙家波,杨建宇,张超,等.应用“资源一号”02C卫星数据的模拟真彩色技术[J].国土资源遥感,2013,25(4):33-39.
[2]	唐新明,丛楠.我国测绘卫星现状与发展思考[J].地理信息世界,2011,9(2):40-44.
[3]	刘斐. 高分一号“高”在哪里[J].太空探索,2013(6):10-11.
[4]	黄琦. “长四乙”成功发射资源一号02C卫星中国航天宇舫发射任务创历史新高[J].太空探索,2012(2):8-8.
[5]	邱学雷. 资源三号卫星投入应用填补空白贡献卓越的“千里眼”[J].国防科技工业,2012(8):24-25.
[6]	邱学雷. 高分一号卫星工程首批影像图发布将为国土、环境、农业等领域提供精准服务[J].国防科技工业,2013(6):14-16.
[7]	Chander G, Markham B.Revised Landsat-5 TM radiometric calibration procedures and postcalibration dynamic ranges[J]. IEEE Transactions on Geoscience and Remote Sensing, 2003,41(11):2674-2677.
[8]	潘志强,傅俏燕,张浩平.CBERS-02星CCD波段平均太阳辐照度反演及应用[J].地球信息科学,2008,10(1):109-113.
[9]	黄琦. 资源一号02C升空[J].中国航天,2012(1):3-3.
[10]	唐新明,谢俊峰.资源三号卫星在轨测试与应用分析[J].地理信息世界,2013,20(2):37-40.
[11]	白照广. 高分一号卫星的技术特点[J].中国航天,2013(8):5-9.
[12]	胡方超,杨若子,陈正超.光谱响应函数对卫星辐射的影响分析[C].第十八届十三省市光学学术会议论文集,2010.
[13]	窦闻,孙洪泉,陈云浩.基于光谱响应函数的遥感图像融合对比研究[J].光谱学与光谱分析,2011,31(3):746-752.
[14]	梅安新,彭望琭,秦其明.遥感导论[M].北京:高等教育出版社,2001.
[15]	方伟,禹秉熙,王玉鹏,等.太阳辐照绝对辐射计及其在航天器上的太阳辐照度测量[J].中国光学与应用光学,2009,2(1):23-28.
[16]	Chance K, Spurr R J D. Ring effect studies: Rayleigh scattering, including molecular parameters for Rotational Raman Scattering and the Fraunhofer spectrum[J]. Applied Optics, 1997,36(21):5224-5230.
[17]	Kurucz R L.The solar irradiance by computation[C]. Proceedings of the 17th Annual Conference on atmospheric transmission models, 1995.
[18]	Neckel H, Labs D.The solar radiation between 3300 and 12500 Angstroms[J]. Solar Physics, 1984,90(2):205-258.
[19]	Thuillier G, Hersé M, Foujols T, et al.The solar spectral irradiance from 200 to 2400 nm as measured by the SOLSPEC spectrometer from the ATLAS and EURECA missions[J]. Solar Physics, 2003,214(1):1-22.
[20]	Wehrli C.Extraterrestrial solar spectrum[J]. World Radiation Center (WRC) Publication, 1985,615(1):10-17.
[21]	胡顺石,张立福,张霞,等.卫星传感器波段平均太阳辐照度计算及可靠性分析[J].国土资源遥感,2012,24(3):97-102.

波段	ESUN_b(W·m^-2·μm^-1)
Band1	1458.01
Band2	1838.90
Band3	1539.99
Band4	1085.64

传感器	波段	ESUN_b(W·m^-2·μm^-1)
MUX	Band1	1955.958
	Band2	1853.249
	Band3	1546.357
	Band4	1084.631
TLC前视相机		1504.762
TLC正视相机		1510.274
TLC后视相机		1499.119

波段	ESUN_b(W·m^-2·μm^-1)
波段	WFV1	WFV2	WFV3	WFV4	PMS1	PMS2
Band1	1968.602	1955.06	1956.562	1968.049	1942.446	1942.8
Band2	1848.374	1846.669	1840.065	1840.845	1851.985	1851.718
Band3	1571.096	1568.999	1541.017	1540.363	1540.964	1541.955
Band4	1078.981	1087.838	1084.041	1069.577	1079.954	1081.075
PAN	-	-	-	-	1370.338	1374.908

波段	最大值	最小值
Band1	1462.581(Kurucz)	1443.836(Thuillier)
Band2	1849.469(Kurucz)	1809.399(Thuillier)
Band3	1546.973(Kurucz)	1524.420(Thuillier)
Band4	1089.208(6S)	1072.719(Thuillier)

传感器	波段	最大值	最小值
MUX	Band1	1985.228(Thuillier)	1929.896(Chance)
	Band2	1860.484(Kurucz)	1824.861(Thuillier)
	Band3	1551.535(Kurucz)	1528.129(Thuillier)
	Band4	1088.085(6S)	1071.494(Thuillier)
TLC前视相机		1511.795(Kurucz)	1492.309(Thuillier)
TLC正视相机		1517.039(Kurucz)	1497.934(Thuillier)
TLC后视相机		1506.065(Kurucz)	1486.747(Thuillier)

国产遥感传感器大气层外波段平均太阳光谱辐照度计算

Calculation of Mean Solar Exoatmospheric Irradiances of Several Sensors Onboard of Chinese Domestic Remote Sensing Satellites

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波段	WFV1		WFV2
波段	最大值	最小值	最大值	最小值
Band1	1996.626(Thuillier)	1930.455(Chance)	1978.770(Thuillier)	1923.869(Chance)
Band2	1854.094(Kurucz)	1818.777(Chance)	1853.250(Kurucz)	1816.156(Thuillier)
Band3	1572.553(Kurucz)	1548.074(Thuillier)	1570.582(Kurucz)	1546.325(Thuillier)
Band4	1081.953(6S)	1064.252(Thuillier)	1091.132(6S)	1075.322(Thuillier)

波段	WFV3		WFV4
波段	最大值	最小值	最大值	最小值
Band1	1979.535(Thuillier)	1920.176(Chance)	1997.109(Thuillier)	1934.138(Chance)
Band2	1848.906(Kurucz)	1808.804(Thuillier)	1848.263(Kurucz)	1810.212(Thuillier)
Band3	1545.114(Kurucz)	1524.958(Thuillier)	1544.553(Kurucz)	1524.561(Thuillier)
Band4	1085.703(6S)	1069.152(Thuillier)	1073.815(6S)	1054.761(Thuillier)

波段	PMS1		PMS2
波段	最大值	最小值	最大值	最小值
Band1	1966.811(Thuillier)	1920.460(Chance)	1967.309(Thuillier)	1920.730(Chance)
Band2	1859.171(Kurucz)	1822.607(Thuillier)	1858.840(Kurucz)	1822.157(Thuillier)
Band3	1547.010(Kurucz)	1523.189(Thuillier)	1547.961(Kurucz)	1524.103(Thuillier)
Band4	1083.241(6S)	1066.547(Thuillier)	1084.330(6S)	1067.720(Thuillier)
PAN	1373.125(6S)	1358.900(Chance)	1377.639(6S)	1363.494(Thuillier)