[1] 沈其荣.土壤肥料学通论[M].北京:高等教育出版社,2001.202. [2] Ben-Dor E,Banin A.Near-infrared analysis as a rapid method to simultaneously evaluate several soil properties[J].Soil Science Society of America Journal,1995,59(2):364-372. [3] 屈晓晖,庄大方,彭望碌,等.基于ANN分类的农田遥感动态监测模型研究[J].自然资源学报,2007(2):193-197. [4] 张春桂,张星,陈敏艳,等.福建近岸海域悬浮泥沙浓度遥感定量监测研究[J].自然资源学报,2008(1):150-160. [5] Kinoshita R,Bianca N,Moebius-Clune B N,et al.Strategies for soil quality assessment using visible and near-infrared reflectance spectroscopy in a Western Kenya Chronosequence[J].Soil Science Society of America Journal,2012,76(5):1776-1788. [6] Vohland M,Ludwig M,Thiele-Bruhn S,et al.Determination of soil properties with visible to near-and mid-infrared spectroscopy:effects of spectral variable selection[J].Geoderma,2014,223-225(1):88-96. [7] Pietrzykowski M,Chodak M.Near infrared spectroscopy-a tool for chemical properties and organic matter assessment of afforested mine soils[J].Ecological Engineering,2014,62(1):115-122. [8] Kuang B,Mouazen A M.Non-biased prediction of soil organic carbon and total nitrogen with vis-NIR spectroscopy,as affected by soil moisture content and texture[J].Biosystems Engineering,2013,114(3):249-258. [9] 王璐,蔺启忠,贾东,等.多光谱数据定量反演土壤营养元素含量可行性分析[J].环境科学,2007,28(8):1822-1828. [10] 李颉,张小超,苑严伟,等.北京典型耕作土壤养分的近红外光谱分析[J].农业工程学报,2012,28(2):176-179. [11] 陈鹏飞,刘良云,王纪华,等.近红外光谱技术实时测定土壤中总氮及磷含量的初步研究[J].光谱学与光谱分析,2008,28(2):295-298. [12] 卢艳丽,白由路,王磊,等.黑土土壤中全氮含量的高光谱预测分析[J].农业工程学报,2010,26(1):256-261. [13] 王磊,顾晓鹤,王宝山,等.基于HJ-1A超光谱影像的县域尺度耕地土壤速效磷含量遥感制图研究[J].土壤通报,2015,46(6):1314-1320. [14] 夏楠,塔西甫拉提·特依拜,丁建丽,等.基于多光谱数据的荒漠矿区土壤有机质估算模型[J].农业工程学报,2016,32(6):263-267. [15] 秦山,潮洛濛.人为干扰对乌海市四合木小灌木景观的影响[J].生态学报,2014,34(21):6346-6354. [16] 李晓明,韩霁昌,李娟.典型半干旱区土壤盐分高光谱特征反演[J].光谱学与光谱分析,2014,34(4):1081-1084. [17] 段鹏程,熊黑钢,李荣荣,等.不同干扰程度的盐渍土与其光谱反射特征定量分析[J].光谱学与光谱分析,2017,37(2):571-576. [18] Tsai F A,William P.A derivative-aided hyperspectral image analysis system for land-cover classification[J].IEEE Transactions on Geoscience and Remote Sensing,2002,10(2):416-425. [19] Tsai F,William P.Derivative analysis of hyperspectral data[J].Remote Sensing of Environment,1998,66(1):41-51. [20] Cloutis E A.Hyperspectral geological remote sensing:evaluation of analytical techniques[J].International Journal of Remote Sensing,1996,17(12):2215-2242. [21] Huang Z,Turner B J,Dury S J,et al.Estimating foliage nitrogen concentration from HYMAP data using continuum removal analysis[J].Remote Sensing of Environment,2004,93(1/2):18-29. [22] Kemper T,Sommer S.Estimate of heavy metal contamination in soils after a mining accident using reflectance spectroscopy[J].Environmental Sciences Technol,2002,36(12):2742. [23] Serrano L,Penuelas J,Ustin S L.Remote sensing of nitrogen and lignin in Mediterranean vegetation from AVIRIS data:decomposing biochemical from structural signals[J].Remote Sensing of Environment,2002,81(2):355-364. [24] 黄敬峰,王福民,王秀珍.水稻高光谱遥感实验研究[M].杭州:浙江大学出版社,2010:22. [25] 曹璞,潘涛,陈星旦.小型近红外玉米蛋白质成分分析仪器设计的波段选择[J].光学精密工程,2007,15(12):1952-1958. [26] Viscarra R V,McGlyn R N,McBratney A B.Determing the composition of mineral-organic mixes using UV-vis-NIR diffuse Reflectance spectroscopy[J].Geoderma,2006,137(1/2):70-82. [27] 刘磊,沈润平,丁国香.基于高光谱的土壤有机质含量估算研究[J].光谱学与光谱分析,2011,31(3):762-766. [28] 侯艳军,塔西甫拉提·特依拜,买买提·沙吾提,等.荒漠土壤有机质含量高光谱估算模型[J].农业工程学报,2014,30(16):113-120. [29] 陶兰花,塔西甫拉提·特依拜,姜红涛,等.克里雅河流域土壤盐分光谱定量分析[J].中国沙漠,2014,34(6):1562-1567. [30] 史舟.土壤地面高光谱遥感原理与方法[M].北京:科学出版社,2014:36. |