Near Real-Time Irrigation Detection at Plot Scale Using Sentinel-1 Data

Hassan Bazzi,Ibrahim Fayad,Valérie Demarez,Nicolas Baghdadi,Mehrez Zribi,Hatem Belhouchette

doi:10.3390/rs12091456

Abstract

In the context of monitoring and assessment of water consumption in the agricultural sector, the objective of this study is to build an operational approach capable of detecting irrigation events at plot scale in a near real-time scenario using Sentinel-1 (S1) data. The proposed approach is a decision tree-based method relying on the change detection in the S1 backscattering coefficients at plot scale. First, the behavior of the S1 backscattering coefficients following irrigation events has been analyzed at plot scale over three study sites located in Montpellier (southeast France), Tarbes (southwest France), and Catalonia (northeast Spain). To eliminate the uncertainty between rainfall and irrigation, the S1 synthetic aperture radar (SAR) signal and the soil moisture estimations at grid scale (10 km × 10 km) have been used. Then, a tree-like approach has been constructed to detect irrigation events at each S1 date considering additional filters to reduce ambiguities due to vegetation development linked to the growth cycle of different crops types as well as the soil surface roughness. To enhance the detection of irrigation events, a filter using the normalized differential vegetation index (NDVI) obtained from Sentinel-2 optical images has been proposed. Over the three study sites, the proposed method was applied on all possible S1 acquisitions in ascending and descending modes. The results show that 84.8% of the irrigation events occurring over agricultural plots in Montpellier have been correctly detected using the proposed method. Over the Catalonian site, the use of the ascending and descending SAR acquisition modes shows that 90.2% of the non-irrigated plots encountered no detected irrigation events whereas 72.4% of the irrigated plots had one and more detected irrigation events. Results over Catalonia also show that the proposed method allows the discrimination between irrigated and non-irrigated plots with an overall accuracy of 85.9%. In Tarbes, the analysis shows that irrigation events could still be detected even in the presence of abundant rainfall events during the summer season where two and more irrigation events have been detected for 90% of the irrigated plots. The novelty of the proposed method resides in building an effective unsupervised tool for near real-time detection of irrigation events at plot scale independent of the studied geographical context.

Highlights

Efficient management of water resources is required to achieve environmentally sustainable development especially under changing climatic conditions and limited water resources
Precipitation records obtained from the Global Precipitation Mission (GPM) data are added to the figures to help understand the consistency between the grid scale σ0G values and the rainfall events
The morning image acquired on 04 September 2017 did not show any detected irrigation since the episodes occurred after the synthetic aperture radar (SAR) acquisition (SAR acquired at 06h00 while irrigation generally takes place after 09h00)

Summary

Introduction

Efficient management of water resources is required to achieve environmentally sustainable development especially under changing climatic conditions and limited water resources. With the decreasing supplies of fresh water due to climate change, better management of irrigation policies is required to deal with the high demand of food and limited water resources. To support the management of irrigated agricultural policies, a spatially detailed quantification of the irrigation extent and timing is required. This quantification is crucial to monitoring fresh water consumption in the agricultural sector especially for regions suffering scarce water resources. The extent and distribution of irrigated areas as well as the irrigation timing remain indefinite especially at large scale. Existing irrigation maps such as the Global Rain-fed, Irrigated and Paddy Croplands (GRIPC) [1] and the Global Map of Irrigated Areas (GMIA) [2] products remain inadequate for irrigation management at plot scale due to their low spatial resolutions (500 m and 5 arc minutes, respectively)

Objectives

Methods

Results

Conclusion