融合作物类型的土壤盐分遥感反演方法研究

doi:10.13474/j.cnki.11-2246.2024.0201

测绘通报 ›› 2024, Vol. 0 ›› Issue (2): 1-7.doi: 10.13474/j.cnki.11-2246.2024.0201

• 全球地表覆盖时空变化研究和应用 • 下一篇

融合作物类型的土壤盐分遥感反演方法研究

张胜男¹, 陆苗¹, 温彩运¹, 宋英强², 康璐¹, 沈军辉³, 杨民志³

1. 北方干旱半干旱耕地高效利用全国重点实验室(中国农业科学院农业资源与农业区划研究所), 北京 100081;
2. 山东理工大学建筑工程与空间信息学院, 山东淄博 255000;
3. 东营市垦利区农业发展服务中心, 山东东营 257500

收稿日期:2023-10-16 发布日期:2024-03-12
通讯作者: 陆苗。E-mail:lumiao@caas.cn
作者简介:张胜男(2000—),女,硕士,研究方向为土壤遥感。E-mail:82101212293@caas.cn
基金资助:
国家重点研发计划(2023YFD200140101);国家自然科学基金(42071419);中国农业科学院科技创新工程(CAAS-ZDRW202201)

Study of soil salinity remote sensing inversion method integrating crop type

ZHANG Shengnan¹, LU Miao¹, WEN Caiyun¹, SONG Yingqiang², KANG Lu¹, SHEN Junhui³, YANG Minzhi³

1. State Key Laboratory of Efficient Utilization of Arid and Semi-arid Arable Land in Northern China(the Institute of Agricultural Resources and Regional Planning, Chinese Academy of Agricultural Sciences), Beijing 100081, China;
2. School of Civil and Architectural Fengineering, Shangdong University of Technology, Zibo 255000, China;
3. Agricultural Development Service Center of Kenli District, Dongying 257500, China

Received:2023-10-16 Published:2024-03-12

摘要/Abstract

摘要： 在沿海平原地区,土壤盐度是制约作物生长的非生物胁迫之一,也是作物种植的重要依据,作物类型能够间接反映土壤盐渍化程度,因此本文提出了一种融合作物类型信息的土壤盐分反演方法。以黄河三角洲典型滨海盐渍土地区为例,基于Sentinel-2 MSI影像,首先采用随机森林分类提取作物类型信息,并基于OneHot方式将作物类型信息编码;然后融合作物类型信息,结合环境协变量数据、地面实测盐分数据,采用自适应增强决策树模型(AB-DT)进行盐分反演;最后与其他机器学习方法,如支持向量机、随机森林、K最邻近和决策树进行盐分反演精度的对比。结果表明:①加入作物类型信息能够提高土壤盐分反演模型精度,所有模型中,融合作物类型变量的AB-DT反演模型精度最高,建模集R²为0.86,测试集R²为0.61; ②加入作物类型信息能够修正误判的盐渍土级别,并使土壤盐分反演结果的地块边缘更加清晰。综上所述,加入作物类型信息,能够提高土壤盐分反演的准确性,为农田管理和农业决策提供更可靠的依据。

关键词: 土壤盐渍化, 多光谱遥感反演, 机器学习

Abstract: In coastal plain regions, soil salinity serves as one of the abiotic stressors limiting crop growth. The content of soil salinity is a critical determinant for crop cultivation. The variety of crops grown can indirectly indicate the extent of soil salinization. Therefore, this paper proposes an integrated approach for the inversion of soil salinity, incorporating crop type information. Based on Sentinel-2 MSI imagery in a typical coastal saline soil area in the Yellow River Delta. Firstly, crop type information was extracted using random forest classification and coded based on the OneHot method. Then, by integrating crop type information, environmental covariate data, and ground-measured salinity data, the adaptive boosting decision tree (AB-DT) model is applied for soil salinity estimation. Finally, the accuracy of salinity estimation is compared with other machine learning methods, including support vector machines, random forests, K-nearest neighbors, and decision trees. The results indicated that ①Incorporating crop type information enhances the accuracy of soil salinity estimation models. Among all models, the AB-DT model with fused crop type variables achieves the highest modeling set R² of 0.86 and validation set R²of 0.61.②The inclusion of crop type information enable to correct misclassifications of salinity levels and yield sharper boundaries in soil salinity estimation results. In conclusion, the incorporation of crop type information improves the accuracy of soil salinity estimation, providing a more reliable basis for agricultural management and decision-making.

Key words: soil salinization, multi-spectral remote sensing estimation, machine learning

中图分类号:

P237

张胜男, 陆苗, 温彩运, 宋英强, 康璐, 沈军辉, 杨民志. 融合作物类型的土壤盐分遥感反演方法研究[J]. 测绘通报, 2024, 0(2): 1-7.

ZHANG Shengnan, LU Miao, WEN Caiyun, SONG Yingqiang, KANG Lu, SHEN Junhui, YANG Minzhi. Study of soil salinity remote sensing inversion method integrating crop type[J]. Bulletin of Surveying and Mapping, 2024, 0(2): 1-7.

参考文献

[1] PERIASAMY S,SHANMUGAM R S. Multispectral and microwave remote sensing models to survey soil moisture and salinity[J]. Land and Degradation ＆ Development,2017,28(4):1412-1425.
[2] ATTWA M,GEMAIL K S,ELERAKI M. Use of salinity and resistivity measurements to study the coastal aquifer salinization in a semi-arid region: a case study in northeast Nile Delta,Egypt[J]. Environmental Earth Sciences,2016,75(9): 18-26.
[3] ALQASEMI A S,IBRAHIM M,AL-QURAISHI A F M,et al. Detection and modeling of soil salinity variations in arid lands using remote sensing data[J]. Open Geosciences,2021,13(1): 443-453.
[4] LI X,LI Y,WANG B,et al. Analysis of spatial-temporal variation of the saline-sodic soil in the west of Jilin Province from 1989 to 2019 and influencing factors[J]. Catena,2022,217: 106492.
[5] LÜ Z Z,LIU G M,YANG J S,et al. Spatial variability of soil salinity in Bohai Sea coastal wetlands,China: partition into four management zones[J]. Plant Biosystems,2013,147(4): 1201.
[6] WU D,JIA K L,ZHANG X D,et al. Remote sensing inversion for simulation of salinization based on hyperspectral data and ground analysis in Yinchuan,China[J]. Natural Resources Research,2021,30:4641-4656.
[7] 厉彦玲,赵庚星,常春艳,等. OLI与HSI影像融合的土壤盐分反演模型[J]. 农业工程学报,2017,33(21): 173-180.
[8] PERRI S,SUWEIS S,HOLMES A,et al. River basin salinization as a form of aridity[J]. Proceedings of the National Academy of Sciences,2020,117(30): 17635-17642.
[9] ALLBED A,KUMAR L. Soil salinity mapping and monitoring in arid and semi-arid regions using remote sensing technology: a review[J]. Advances in Remote Sensing,2013,2(4):373-385.
[10] 张素铭,赵庚星,王卓然,等. 滨海盐渍区土壤盐分遥感反演及动态监测[J]. 农业资源与环境学报,2018,35(4): 349-358.
[11] 张同瑞,赵庚星,高明秀,等. 基于近地面多光谱的黄河三角洲典型地区土壤含盐量估算研究[J]. 光谱学与光谱分析,2016,36(1): 248-253.
[12] FERNÁNDEZ-BUCES N,SIEBE C,CRAM S,et al.Mapping soil salinity using a combined spectral response index for bare soil and vegetation: a case study in the former lake Texcoco,Mexico[J]. Journal of Arid Environments,2006,65(4):644-667.
[13] ELDEIRY A A,GARCIA L A. Comparison of ordinary Kriging,regression Kriging,and coKriging techniques to estimate soil salinity using Landsat images[J]. Journal of Irrigation and Drainage Engineering,2010,136(6): 355-364.
[14] WU W,MHAIMEED A S,AL-SHAFIE W M,et al,Mapping soil salinity changes using remote sensing in Central Iraq[J]. Geoderma Regional,2014,2-3: 21-31.
[15] SETIA R,LEWIS M,MARSCHNER P,et al. Severity of salinity accurately detected and classified on a paddock scale with high resolution multispectral satellite imagery[J]. Land Degradation ＆ Development,2011,24(4): 375- 384.
[16] SIDIKE A,ZHAO S,WEN Y. Estimating soil salinity in Pingluo County of China using QuickBird data and soil reflectance spectra[J]. International Journal of Applied Earth Observation and Geoinformation,2014,26: 156-175.
[17] 孙玉松. 黄三角濒海区冬小麦长势遥感指标及其土壤盐分反演[D]. 泰安: 山东农业大学,2021.
[18] 唐娜,崔保山,赵欣胜. 黄河三角洲芦苇湿地的恢复[J]. 生态学报,2006,26(8): 2616-2624.
[19] 齐广慧. 黄三角濒海区主要作物土壤盐分的星机地一体化反演方法研究[D]. 泰安: 山东农业大学,2022.
[20] 侯贺贺,王春堂,王晓迪,等. 黄河三角洲盐碱地生物措施改良效果研究[J]. 中国农村水利水电,2014(7): 1-6.
[21] 胡盈盈,王瑞燕,陈红艳,等. 黄河三角洲春秋两季土壤盐分遥感反演及时空变异研究[J]. 测绘与空间地理信息,2018,41(8): 78-81.
[22] 周晓红,张飞,张海威,等. 艾比湖湿地自然保护区土壤盐分多光谱遥感反演模型[J]. 光谱学与光谱分析,2019,39(4): 1229-1235.
[23] 奚雪,赵庚星,高鹏,等. 基于Sentinel卫星及无人机多光谱的滨海冬小麦种植区土壤盐分反演研究: 以黄三角垦利区为例[J]. 中国农业科学,2020,53(24): 5005-5016.
[24] GAO Bing,YANG Fei,HAN Baomin,et al. A model for the rapid monitoring of soil salinization in the Yellow River Delta using Landsat 8 OLI imagery based on VI-SI feature space[J]. Remote Sensing Letters,2019,10(8):796-805.
[25] WANG J,DING J,YU D,et al. Machine learning-based detection of soil salinity in an arid desert region,Northwest China: a comparison between Landsat-8 OLI and Sentinel-2 MSI[J]. Science of the Total Environment,2020,707: 136092.
[26] DEHNI A,LOUNIS M. Remote sensing techniques for salt affected soil mapping: application to the Oran Region of Algeria[J]. Procedia Engineering 2012,33: 188-198.
[27] 何宝忠,丁建丽,刘博华,等. 渭库绿洲土壤盐渍化时空变化特征[J]. 林业科学,2019,55(9): 185-196.

融合作物类型的土壤盐分遥感反演方法研究

Study of soil salinity remote sensing inversion method integrating crop type

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