Spatial mapping of soil moisture content using very-high resolution UAV-based multispectral image analytics

IF 6.3 Q1 AGRICULTURAL ENGINEERING
Suyog Balasaheb Khose, Damodhara Rao Mailapalli
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Abstract

Assessing soil moisture content (SMC) is necessary for managing water at a spatial scale. Remote sensing technologies provide a robust approach for detecting the spatial-temporal fluctuations of SMC. The aim of this study was to estimate SMC at different soil depths using very high-resolution unmanned aerial vehicle (UAV)-based multispectral (MS) images and machine learning algorithms and generate spatial maps of SMC using the best-performed machine learning (ML) algorithm. The UAV-based multispectral images of bare soil were captured at 40 m altitude with a very high spatial resolution (2.89 cm) during the rabi 2021/22 season. At the same time, the soil samples were collected from different soil depths, and the gravimetric SMC was measured. Five machine-learning algorithms (Linear Regression (LR), K-Nearest Neighbors (KNN), Random Forest (RF), Decision Tree (DT), and Support Vector Regression (SVR)) were used to train the model between SMC and MS data (MS band reflectance and vegetation indices). The soil with high SMC has low spectral reflectance and soil with low SMC shows high spectral reflectance. For the prediction of surface SMC, the linear regression (R2 = 0.89; RMSE = 2.80 %) and 5 cm depth SMC, the SVR (R2 = 0.64; RMSE = 3.03 %) were performed well compared to other ML algorithms. For surface SMC, blue band reflectance, and 5 cm depth SMC, the Ratio Vegetation Index (RVI) correlated well compared to others. All models failed to predict the SMC at the deeper soil depths. The spatial SMC mapping described the visual color variations in SMC within the field. Crop irrigation scheduling can be significantly improved through the insights this spatial SMC estimation approach provides, making it a valuable tool for farmers and irrigation planners.

利用超高分辨率无人机多光谱图像分析技术绘制土壤含水量空间图
评估土壤含水量(SMC)对于在空间尺度上管理水资源十分必要。遥感技术为检测土壤含水量的时空波动提供了一种可靠的方法。本研究的目的是利用基于无人机(UAV)的高分辨率多光谱(MS)图像和机器学习算法估算不同土壤深度的 SMC,并利用表现最佳的机器学习(ML)算法生成 SMC 空间图。基于无人机的裸土多光谱图像是在 2021/22 旱季期间在 40 米高空以极高的空间分辨率(2.89 厘米)拍摄的。同时,从不同土壤深度采集了土壤样本,并测量了重力SMC。采用五种机器学习算法(线性回归(LR)、K-近邻(KNN)、随机森林(RF)、决策树(DT)和支持向量回归(SVR))来训练 SMC 与 MS 数据(MS 波段反射率和植被指数)之间的模型。高 SMC 的土壤光谱反射率低,低 SMC 的土壤光谱反射率高。在预测地表 SMC 和 5 厘米深度 SMC 时,与其他 ML 算法相比,线性回归(R2 = 0.89;RMSE = 2.80 %)和 SVR(R2 = 0.64;RMSE = 3.03 %)表现良好。对于地表 SMC、蓝带反射率和 5 厘米深度 SMC,植被比值指数(RVI)与其他算法的相关性较好。所有模型都无法预测土壤深处的 SMC。空间 SMC 地图描述了田间 SMC 的视觉颜色变化。通过这种空间 SMC 估算方法可以显著改善作物灌溉调度,使其成为农民和灌溉规划人员的宝贵工具。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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CiteScore
4.20
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