Cross-scale soil moisture content monitoring of winter wheat by integrating UAV and sentinel-1/2 data

IF 6.5 1区农林科学 Q1 AGRONOMY

Agricultural Water Management Pub Date : 2025-09-23 DOI:10.1016/j.agwat.2025.109831

Xingjiao Yu , Qi Yin , Long Qian , Chaoyue Zhang , Lingjia Shao , Danjie Ran , Wen’e Wang , Baozhong Zhang , Xiaotao Hu

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引用次数: 0

Abstract

Accurate estimation of soil moisture content (SMC) is critical for agricultural irrigation, water resource management, and monitoring the ecological environment. The development of multi-sensor UAV platforms offers a novel approach to cross-scale SMC monitoring. This study presents an innovative framework that integrates ground, UAV, and satellite data to estimate SMC and generate county-scale spatial distribution maps of SMC in winter wheat fields. Firstly, UAV images were utilized at the subplot scale to extract winter wheat planting areas through supervised classification, and SMC was estimated by employing partial least squares regression (PLSR). Subsequently, the UAV SMC mapping results were upscaled and integrated with Sentinel-1 synthetic aperture radar (SAR) features and Sentinel-2 multispectral features to develop XGBoost-based satellite-scale SMC estimation model. The study demonstrated that at the plot scale, combining vegetation indices and texture features achieved the highest accuracy (0–20 cm: R² = 0.775, RMSE = 0.018 m³/m³; 20–40 cm: R² = 0.723, RMSE = 0.021 m³/m³). At the satellite scale, the XGBoost model also performed well (0–20 cm: R² = 0.901, RMSE = 0.0071 m³/m³; 20–40 cm: R² = 0.884, RMSE = 0.011 m³/m³). Furthermore, compared to traditional ground-satellite models, the integrated ground-UAV-satellite approach improved accuracy, with R² increasing by 9.53–10.52 %, RMSE decreasing by 11.11–1.25 %, and MAE reducing by 18.19–25.00 %. This cross-scale remote sensing framework enhances SMC monitoring efficiency and accuracy, offering a robust solution for large-scale applications.

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基于无人机与sentinel-1/2数据的冬小麦土壤水分监测

土壤含水量的准确估算对农业灌溉、水资源管理和生态环境监测具有重要意义。多传感器无人机平台的发展为跨尺度SMC监测提供了新的途径。该研究提出了一个创新的框架，将地面、无人机和卫星数据集成在一起，估算冬小麦麦田SMC并生成县域尺度的SMC空间分布图。首先，在子样地尺度上利用无人机影像，通过监督分类提取冬小麦种植面积，并利用偏最小二乘回归（PLSR）估计最小二乘面积。随后，将无人机SMC制图结果进行升级，并与Sentinel-1合成孔径雷达（SAR）特征和Sentinel-2多光谱特征相结合，开发基于xgboost的卫星尺度SMC估计模型。研究表明，在样地尺度上，结合植被指数和纹理特征获得了最高的精度（0-20 cm: R2 = 0.775, RMSE = 0.018 m3/m3; 20-40 cm: R2 = 0.723, RMSE = 0.021 m3/m3）。在卫星尺度上，XGBoost模型也表现良好（0-20 cm: R2 = 0.901, RMSE = 0.0071 m3/m3; 20-40 cm: R2 = 0.884, RMSE = 0.011 m3/m3）。此外，与传统地面-卫星模型相比，地面-无人机-卫星综合方法提高了精度，R2提高了9.53 ~ 10.52 %，RMSE降低了11.11 ~ 1.25 %，MAE降低了18.19 ~ 25.00 %。这种跨尺度遥感框架提高了SMC监测的效率和精度，为大规模应用提供了强大的解决方案。

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来源期刊

Agricultural Water Management 农林科学-农艺学

CiteScore

12.10

自引率

14.90%

发文量

648

审稿时长

4.9 months

期刊介绍： Agricultural Water Management publishes papers of international significance relating to the science, economics, and policy of agricultural water management. In all cases, manuscripts must address implications and provide insight regarding agricultural water management.