无人机多光谱反演黄河口重度盐渍土盐分的研究  被引量：19

作　　者：王丹阳 陈红艳[1] 王桂峰 丛津桥 王向锋[4] 魏学文 WANG DanYang;CHEN HongYan;WANG GuiFeng;CONG JinQiao;WANG XiangFeng;WEI XueWen(National Engineering Laboratory for Efficient Utilization of Soil and Fertilizer Resources/College of Resources and Environment,Shandong Agricultural University,Taian 271018,Shangdong;Shandong Cotton Production Technical Guidance Station,Jinan 250000;Taishan Natural Resources Bureau,Taian 271000,Shangdong;Kenli Land and Resources Bureau, Dongyin 27500,Shangdong)

机构地区：[1]土肥资源高效利用国家工程实验室/山东农业大学资源与环境学院,山东泰安271018 [2]山东省棉花生产技术指导站,济南250000 [3]泰山区自然资源局,山东泰安271000 [4]垦利区国土资源局,山东东营27500

出　　处：《中国农业科学》2019年第10期1698-1709,共12页Scientia Agricultura Sinica

基　　金：国家自然科学基金(41877003;41671346);山东省自然科学基金(ZR2019MD039);山东省重点研发计划(2017CXGC0306);"十二五"国家科技支撑计划(2015BAD23B0202);山东农业大学"双一流"奖补资金(SYL2017XTTD02)

摘　　要：【目的】为提高土壤盐分信息定量遥感提取精度,准确掌握土壤盐渍化程度与分布。【方法】选择垦利区黄河口镇集中连片的重度盐渍土区域为试验区,于2018年4月26日—28日采用搭载Sequoia多光谱相机的无人机进行试验区近地遥感图像采集,并进行图像拼接、辐射校正、正射校正和几何校正等预处理;然后基于相关性分析、灰色关联度分析筛选土壤盐分的敏感波段,构建并筛选光谱参量;进而分别采用多元线性回归(multivariable linear regression,MLR)、支持向量机(support vector machine,SVM)及偏最小二乘(partial least square,PLS)方法构建土壤盐分定量反演模型,并进行验证与评价;最后基于最佳模型进行试验区土壤盐分的分布反演与分析,并与反距离加权插值结果进行精度比较。【结果】相较相关性分析,通过灰色关联度分析的反演模型精度及显著性均有所提高;对比3种建模方法,SVM模型精度最高,PLS模型次之,MLR模型最低,最佳模型为基于灰色关联度分析筛选变量的支持向量机模型,其建模R^2、RMSE分别为0.820、3.626,验证R^2、RMSE、RPD分别为0.773、4.960、2.200;据此模型反演得到该区域土壤盐分含量为0.323—21.210 g·kg^(-1),平均值为6.871 g·kg^(-1),重度盐渍土占58.094%,与实地调查结果较为一致;反演结果与反距离加权插值结果的误差80%控制在样本盐分含量平均值的20%以内,亦较为相近。【结论】基于无人机多光谱可实现重度盐渍土盐分信息的准确提取。【Objective】The purpose of this paper was to improve the extraction accuracy of soil salinity information based on remote sensing and understand accurately the degree and distribution of soil salinization.【Method】Firstly, the severe and concentrated saline soil area of Huanghekou town, Kenli district, was selected as the experimental area, and the unmanned aerial vehicle (UAV) equipped with Sequoia multispectral camera was adopted to acquire the near earth remote sensing image from April 26th to 28th, 2018, then the image preprocessing, including image splicing, radiation correction, orthorectification and geometric correction, was performed. Secondly, the sensitive bands of soil salinity were screened by correlation analysis and grey correlation analysis, respectively, and the spectral parameters were constructed and screened. Thirdly, the soil salinity quantitative analysis models were built by multivariate linear regression (MLR), support vector machine (SVM) and partial least square (PLS) method, then the models’ accuracy was evaluated and the best one was selected. Finally, the best model was applied to the inversion and analysis of soil salinity distribution in the experimental area, and the inversion accuracy was compared with the interpolation result by inverse distance weighting (IDW) method.【Result】The results showed that the accuracy and significance of the estimation model based on gray correlation analysis were improved by compared with the correlation analysis;Compared the three modeling methods, the prediction ability of the SVM was the best, followed by the PLS, the MLR models’ precision was the lowest, with the calibration R2 and RMSE of 0.820 and 3.626, the validation R2, RMSE and RPD of 0.773, 4.960 and 2.200, and the SVM model of soil salinity based on screened variables by grey correlation analysis was selected the best one;Based on the best model, the soil salinity content in this region was between 0.323 and 21.210 g·kg^-1 with the average of 6.871 g·kg^-1 and the severe sa

关 键 词：无人机 多光谱 盐渍土 灰色关联度 黄河口 

分 类 号：S156.41[农业科学—土壤学] TP751[农业科学—农业基础科学]