Prediction of soil nutrients through PLSR and SVMR models by VIs-NIR reflectance spectroscopy

IF 3.7 3区地球科学 Q2 ENVIRONMENTAL SCIENCES

Egyptian Journal of Remote Sensing and Space Sciences Pub Date : 2023-11-10 DOI:10.1016/j.ejrs.2023.10.005

Chiranjit Singha , Kishore Chandra Swain , Satiprasad Sahoo , Ajit Govind

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引用次数: 0

Abstract

Though soil nutrients play important roles in maintaining soil fertility and crop growth, their estimation requires direct soil sampling followed by laboratory analysis incurring huge cost and time. In this research work, soil nutrients were predicted using VIs-NIR reflectance spectroscopy (range 350–2500 nm) with Partial Least Squares Regression (PLSR) and Support Vector Machine Regression Model (SVMR) model through principal component analysis. Two hundred soil samples were collected from Tarekswar, Hooghly, West Bengal, India to predict eight selected soil nutrients, such as soil organic carbon (OC), pH, available nitrogen (N), available phosphorus (P), available potassium(K), electric conductivity (EC), zinc (Zn) and soil texture (sand, silt, and clay) levels. The OC content was predicted with sound accuracy (R²: 0.82, RPD: 2.28, RMSE: 0.13, RPIQ: 4.15 FD-SG), followed by P (R²: 0.71, RPD: 1.83, RMSE: 4575, RPIQ: 3.44 1st derivative). The soil parameters sensitive to the particular band of visible spectrum were also identified viz. wavelengths of 409, 444, 591 and 592 nm for OC, 430 and 505 nm for P, 464 nm for K; 580 nm for Zn, 492,511,596 and 698 nm for N; 493, 569 and 665 nm for EC; 492,567 and 652 nm for pH; 457 nm for sand and 515 nm for clay.

The soil nutrient levels were predicted by PLSR and SVMR models through PCA and Sentinel 2 imagery and soil suitability map were also generated for seven soil parameters such as OC, pH, EC, N, P, K and clay content. Through map query tool in ArcGIS software environment the PLSR and SVMR model successfully identify the suitability class with level of accuracy of 87.2% and 88.9%, respectively, against the direct soil analysis based suitability mapping.

The machine learning technique based soil nutrient and soil suitability prediction can be easily adopted in different regions. This will reduce the cost of laboratory soil analysis and optimize the total time requirement.

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利用PLSR和SVMR模型预测土壤养分的VIs-NIR反射光谱

虽然土壤养分在维持土壤肥力和作物生长方面发挥着重要作用，但它们的估算需要直接取样，然后进行实验室分析，成本和时间都很大。本研究利用VIs-NIR光谱(350 ~ 2500 nm)，结合偏最小二乘回归(PLSR)和支持向量机回归模型(SVMR)，通过主成分分析对土壤养分进行预测。从印度西孟加拉邦胡格利的塔里克斯瓦尔收集了200个土壤样本，以预测8种选定的土壤养分，如土壤有机碳(OC)、pH、有效氮(N)、有效磷(P)、有效钾(K)、电导率(EC)、锌(Zn)和土壤质地(砂、粉和粘土)水平。预测OC含量精度较高(R2: 0.82, RPD: 2.28, RMSE: 0.13, RPIQ: 4.15)， P值较高(R2: 0.71, RPD: 1.83, RMSE: 4575, RPIQ: 3.44)。土壤参数对特定可见光谱波段的敏感性为:OC的波长为409、444、591和592 nm, P的波长为430和505 nm, K的波长为464 nm;Zn为580 nm, N为492,511,596和698 nm;EC为493,569和665 nm;pH值492,567和652 nm;沙子为457nm，粘土为515nm。利用PLSR和SVMR模型，结合PCA和Sentinel 2影像对土壤养分水平进行了预测，并生成了OC、pH、EC、N、P、K和粘土含量等7个土壤参数的土壤适宜性图。通过ArcGIS软件环境下的地图查询工具，PLSR和SVMR模型相对于基于土壤直接分析的适宜性制图，分别以87.2%和88.9%的准确率成功识别出适宜性等级。基于机器学习技术的土壤养分和适宜性预测可以很容易地应用于不同的区域。这将降低实验室土壤分析的成本，并优化总时间要求。

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来源期刊

Egyptian Journal of Remote Sensing and Space Sciences Multiple-

CiteScore

8.10

自引率

0.00%

发文量

审稿时长

48 weeks

期刊介绍： The Egyptian Journal of Remote Sensing and Space Sciences (EJRS) encompasses a comprehensive range of topics within Remote Sensing, Geographic Information Systems (GIS), planetary geology, and space technology development, including theories, applications, and modeling. EJRS aims to disseminate high-quality, peer-reviewed research focusing on the advancement of remote sensing and GIS technologies and their practical applications for effective planning, sustainable development, and environmental resource conservation. The journal particularly welcomes innovative papers with broad scientific appeal.