基于最大熵估计Alpha谱缩放与平移量的温度与发射率分离算法

刘俊池; 李洪文; 王建立; 刘欣悦; 马鑫雪

doi:10.7498/aps.64.175205

摘要

在热红外波段, 为了使温度与发射率分离过程不依赖数据库提供的经验信息, 并且实现更高的反演精度和更快的计算速度, 研究了一种新的温度与发射率分离算法. 首先, 在维恩近似原理的基础上, 求解了Alpha谱分布, 并利用Alpha谱描述光谱发射率的形状信息. 其次, 改进了最大熵温度与发射率分离算法: 应用最大熵估计模型对Alpha谱缩放与平移量进行估计, 减少了待估计参数的数量, 大幅简化了求解过程. 最后, 进行了算法的数值仿真实验: 求解了典型地物目标的温度与光谱发射率, 并且分析了算法对系统噪声的鲁棒性. 仿真数据表明: 发射率估计的最大RMSE为0.017, 温度估计的最大绝对误差的绝对值为0.62 K; 对系统添加测量信噪比为11的高斯白噪声, 发射率估计的相对RMSE为2.67%, 温度估计的相对误差为1.26%. 结果表明: 本文所述算法求解精度高, 计算速度快, 具备良好的鲁棒性.

关键词:

温度 /
发射率 /
Alpha谱 /
最大熵

Abstract

In the thermal infrared (TIR) waveband, solving the target emissivity spectrum and temperature leads to an ill-posed problem in which the number of unknown parameters is larger than that of available measurements. Generally, the approaches developed for solving this kind of problems are called, by a joint name, the TES (temperature and emissivity separation) algorithm. As is shown in the name, the TES algorithm is dedicated to separating the target temperature and emissivity in the calculating procedure. In this paper, a novel method called the new MaxEnt (maximum entropy) TES algorithm is proposed, which is considered as a promotion of the MaxEnt TES algorithm proposed by Barducci. The maximum entropy estimation is utilized as the basic framework in the two preceding algorithms, so that the two algorithms both could make temperature and emissivity separation, independent of experiential information derived by some special data bases. As a result, the two algorithms could be applied to solve the temperature and emissivity spectrum of the targets which are absolutely unknown to us. However, what makes the two algorithms different is that the alpha spectrum derived by the ADE (alpha derived emissivity) method is considered as priori information to be added in the new MaxEnt TES algorithm. Based on the Wien approximation, the ADE method is dedicated to the calculation of the alpha spectrum which has a similar distribution to the true emissivity spectrum. Based on the preceding promotion, the new MaxEnt TES algorithm keeps a simpler mathematical formalism. Without any doubt, the new MaxEnt TES algorithm provides a faster computation for large volumes of data (i.e. hyperspectral images of the Earth). Some numerical simulations have been performed; the data and results show that, the maximum RMSE of emissivity estimation is 0.017, the maximum absolute error of temperature estimation is 0.62 K. Added with Gaussian white noise in which the signal to noise ratio is measured to be 11, the relative RMSE of emissivity estimation is 2.67%, the relative error of temperature estimation is 1.26%. Conclusion shows that the new MaxEnt TES algorithm may achieve high accuracy and fast calculating speed, and also get nice robustness against noise.

Keywords:

作者及机构信息

1.
中国科学院长春光学精密机械与物理研究所, 长春 130033;

2.
中国科学院大学, 北京 100049

通信作者: 李洪文, lihongwen1970@yahoo.com

基金项目: 国家高技术研究发展计划(批准号: 2014AAXXX1003X)资助的课题.

Authors and contacts

1.
Changchun Institute of Optics, Fine Mechanics and Physics, Chinese Academy of Sciences, Changchun 130033, China;

2.
University of Chinese Academy of Sciences, Beijing 100049, China

Corresponding author: Li Hong-Wen, lihongwen1970@yahoo.com

Funds: Project supported by the National High Technology Research and Development Program of China (Grant No. 2014AAXXX1003X).

参考文献

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[9]	Yang H, Zhang L F, Zhang X W, Fang C H, Tong Q X 2011 Journal of Remote Sensing 15 1242 (in Chinese) [杨杭, 张立福, 张学文, 房丛卉, 童庆禧 2011 遥感学报 15 1242]
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[16]	Barducci A, Pippi I 1996 IEEE Trans. Geosci. Remote Sensing 34 681
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施引文献

[1]	Liu E C, Zheng X B, Li X, Zhang Y N 2013 Optics and Precision Engineering 21 608 (in Chinese) [刘恩超, 郑小兵, 李新, 张艳娜 2013 光学精密工程 21 608]
[2]	Yang C Y, Cao L H, Zhang J P 2014 Optics and Precision Engineering 22 1751 (in Chinese) [杨词银, 曹立华, 张建萍 2014 光学精密工程 22 1751]
[3]	Li N, Zhang Y F, Liu C X, Cao L H, Guo L H 2014 Optics and Precision Engineering 22 2054 (in Chinese) [李宁, 张云峰, 刘春香, 曹立华, 郭立红 2014 光学精密工程 22 2054]
[4]	Kealy P S, Hook S J 1993 IEEE Trans. Geosci. Remote Sensing 31 1155
[5]	Wan Z, Li Z L 1997 IEEE Trans. Geosci. Remote Sensing 35 980
[6]	Li Z L, Becker F, Stoll M P, Wang Z 1990 Remote Sensing of Environments 69 197
[7]	Gillespie A, Rokugawa S, Matsunaga T, Cothern J S, Hook S, Kahle A B 1998 IEEE Trans. Geosci. Remote Sensing 36 1113
[8]	Xu Z, Zhao H J 2009 Acta Optica Sinica 29 394 (in Chinese) [徐州, 赵慧洁 2009 光学学报 29 394]
[9]	Yang H, Zhang L F, Zhang X W, Fang C H, Tong Q X 2011 Journal of Remote Sensing 15 1242 (in Chinese) [杨杭, 张立福, 张学文, 房丛卉, 童庆禧 2011 遥感学报 15 1242]
[10]	Kahle A B, Madura D P, Soha J M 1980 Applied Optics 19 2279
[11]	Wan Z, Dozier J 1989 IEEE Trans. Geosci. Remote Sensing 27 268
[12]	Tang S H, Zhu Q J, Su L H 2005 J. Infrared Millim. Waves 24 286 (in Chinese) [唐世浩, 朱启疆, 苏理宏 2005 红外与毫米波学报 24 286]
[13]	Price J C 1984 J. Geophys. Res. 89 7231
[14]	Morgan J A 2005 IEEE Trans. Geosci. Remote Sensing 43 1279
[15]	Liu Y J, Yang Z D 2001 Principle and Algorithm of Remote Sensing Information Processing for MODIS (Beijing: Sciences Press) p232 (in Chinese) [刘玉洁, 杨忠东 2001 MODIS遥感信息处理原理与算法(北京: 科学出版社) 第232页]
[16]	Barducci A, Pippi I 1996 IEEE Trans. Geosci. Remote Sensing 34 681
[17]	Barducci A, Guzzi D, Lastri C, Marcoionni P, Nardino V, Pippi I 2014 IEEE Trans. Geosci. Remote Sensing 53 738
[18]	Barducci A, Guzzi D, Lastri C, Marcoionni P, Nardino V, Pippi I 2013 Infrared Physics & Technology 56 12
[19]	Kealy P S, Gabell A R 1990 Proc. 2nd TIMS Workshop JPL Pub 90-55 11-15
[20]	Jiang X K, Zhang Q C, Shi H T, Mao L, Cheng T, Wu X P 2011 Acta Phys. Sin. 60 054401 (in Chinese) [蒋兴凯, 张青川, 史海涛, 毛亮, 程腾, 伍小平 2011 物理学报 60 054401]
[21]	Zhou Y P, Li F J, Che C, Tan L Y, Ran Q W, Yu S Y, Ma J 2014 Acta Phys. Sin. 63 148501 (in Chinese) [周彦平, 黎发军, 车驰, 谭立英, 冉启文, 于思源, 马晶 2014 物理学报 63 148501]
[22]	Sun C M, Yuan Y, Zhang X B 2010 Acta Phys. Sin. 59 7523 (in Chinese) [孙成明, 袁艳, 张修宝 2010 物理学报 59 7523]

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