| 光谱学与光谱分析 |
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| Soil Taxonomy on the Basis of Reflectance Spectral Characteristics |
| LIU Huan-jun1,2,ZHANG Bai1,ZHANG Yuan-zhi3,SONG Kai-shan1,WANG Zong-ming1*,LI Fang1,2,HU Mao-gui1,2 |
1. Northeast Institute of Geography and Agricultural Ecology,Chinese Academy of Sciences,Changchun 130012,China
2. Graduate University of Chinese Academy of Sciences,Beijing 100039,China
3. Institute of Space and Earth Information Science,the Chinese University of Hong Kong,Shatin,N.T.,Hong Kong,China |
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Abstract Soil spectral reflectance is the comprehensive representation of soil physical and chemical parameters,and its study is the physical basis for soil remote sensing and provides a new way and standard for soil properties themselves’ research. Soil room spectra significantly correlate with that derived from hyperspectral images. So the room spectra are very important for soil taxonomy and investigation. To seek for the feasibility of soil taxonomy on the basis of topsoil reflectance spectral characteristics,and provide the theory foundation for quick soil taxonomy based on remote sensing methods,the spectral reflectance in the visible and near infrared region (400-2 500 nm) of 248 soil samples (black soil,chernozem,meadow soil,blown soil,alluvial soil) collected from Nongan county,Jilin province was measured with a hyperspectral device in room,and the soil spectral characteristics were determined with continuum removal method,and soil spectral indices (spectral absorption area,depth and asymmetry) were computed,which were introduced into BP network models as external input variables. The models consist of three layers (input,output and hidden layer),the training function is “TRAINLM”,learning function “LEARNGDM”,and transferring function “TANSIG”. The results showed that: (1) There are some differences among different soils in their spectral characteristics,but with similar parental matrix and climate,the spectral differences of soils in Nongan county are not significant. So it’s difficult to analyze soil spectral characteristics based on soil reflectance. (2) The curves after continuum removal strengthened soil spectral absorption characteristics,and simplified soil spectral analysis. The soil spectral curves in Nongan county mainly have five spectral absorption vales at 494,658,1 415,1 913 and 2 206 nm,and the former two vales are caused by soil organic matter,Fe and mechanical composition,the latter three are due to soil moisture; the differences of the latter three vales among different soils are not apparent,and the significant differences are in the former two vales region. (3) Soil reflectance is sensitive to organic matter,soil moisture,Fe,mechanical composition,roughness,and so on. The sensitivity of soil spectral indices derived with continuum removing method is decreased. Then the models with these indices as input variables are more stable and general. As the input variables were external,the BP network model based on the former two vales’ shape characteristics was better than that based on reflectance values or all five vales,the classifying accuracy of the main three soils (chernozem,meadow soil,blown soil) was bigger than 60%,and the model could be used for soil taxonomy. However,this work still needs further study,and to improve classifying accuracy,auxiliary data,such as topography,vegetation,and land use should be introduced.
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Received: 2007-05-10
Accepted: 2007-08-20
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Corresponding Authors:
WANG Zong-ming
E-mail: zongmingwang@neigae.ac.cn
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[1] HUANG Ying-feng,LIU Teng-hui(黄应丰,刘腾辉). Chinese Journal of Soil Science(土壤通报),1989,20(4): 158,176.
[2] Palacios-Orueta A,Ustin S L. Remote Sensing of Environment,1998,65: 170.
[3] McBratney A,Minasny B,Rossel R A V. Geoderma,2006,136: 272.
[4] SUN Jian-ying,LI Min-zan,ZHENG Li-hua,et al(孙建英,李民赞,郑立华,等). Spectroscopy and Spectral Analysis(光谱学与光谱分析),2006,26(3): 426.
[5] Dobos E,Montanarella L,Negre T,et al. Journal of Applied Earth Observations and Geoinformation,2001,3(1): 30.
[6] Goetz A F H,Vane G,Solomon J E,et al. Science,1985,228: 1147.
[7] ZHAO Ying-shi(赵英时). Theory and Method of Remote Sensing Application Analysis(遥感应用分析原理与方法). Beijing: Science Press(北京:科学出版社),2003. 95.
[8] Ben-Dor E,Patkin K,Banin A,et al. Int. J. Remote Sensing,2002,23(6): 1043.
[9] Chang C W,Laird D A. Soil Sci.,2002,167(2): 110.
[10] David B L,Gregory P A. Soil Sci. Soc. Am. J.,2002,66: 722.
[11] Krishnan P,Alexander J D,Butler B J,et al. Soil Sci. Soc. Am. J.,1980,44: 1282.
[12] Liu W D,Baret F,Gu X F,et al. Remote Sensing of Environment,2002,81: 238.
[13] Michael L W,Lin L,Susan L U. Remote Sensing of Environment,2004,89: 535.
[14] Dehaan R L,Taylor G R. Remote Sensing of Environment,2002,80: 406.
[15] Kooistra L,Wehrens R,Leuven R,et al. Analytica Chimica Acta,2001,446: 97.
[16] Leone A P,Sommer S. Remote Sensing Environment,2000,72: 346.
[17] GAO Rong-qiang,FAN Shi-fu,YAN Yan-lu,et al(高荣强,范世福,严衍禄,等). Spectroscopy and Spectral Analysis(光谱学与光谱分析),2004,24(12): 1563.
[18] HE Ting,WANG Jing,CHENG Ye,et al(何 挺,王 静,程 烨,等). Geography and Geo-Information Science(地理与地理信息科学),2006,21(1): 23.
[19] PU Rui-liang,GONG Peng(浦瑞良,宫 鹏). Hyperspectral Remote Sensing and Its Applications(高光谱遥感及其应用). Beijing: Higher Education Press(北京: 高等教育出版社),2000. 53.
[20] LIU Huan-jun,ZHANG Bai,ZHAO Jun,et al(刘焕军,张 柏,赵 军,等). Acta Pedologica Sinica(土壤学报),2007,44(1): 27.
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