Abstract
This study aims to propose an operational approach to map irrigated areas based on the synergy of Sentinel-1 (S1) and Sentinel-2 (S2) data. An application is proposed at two study sites in Europe—in Spain and in Italy—with two climatic contexts (semiarid and humid, respectively), with the objective of proving the essential role of multi-site training for a robust application of the proposed methodologies. Several classifiers are proposed to separate irrigated and rainfed areas. They are based on statistical variables from Sentinel-1 and Sentinel-2 time series data at the agricultural field scale, as well as on the contrasted behavior between the field scale and the 5 km surroundings. The support vector machine (SVM) classification approach was tested with different options to evaluate the robustness of the proposed methodologies. The optimal number of metrics found is five. These metrics illustrate the importance of optical/radar synergy and the consideration of multi-scale spatial information. The highest accuracy of the classifications, approximately equal to 85%, is based on training dataset with mixed reference fields from the two study sites. In addition, the accuracy is consistent at the two study sites. These results confirm the potential of the proposed approaches towards the most general use on sites with different climatic and agricultural contexts.
Highlights
Water resource management is a key issue in climate change, considering the increasing number of drought events as well as the increase in water use for irrigation [1–6]
We observe that for training at the Spanish site, four parameters—μ (VV_field), μ (VH/VV_field), μ (NDVI_field), and μ (VV_5 km)/μ (VV_field)—illustrate close contributions. These results illustrate a significant contribution from the μ (VV_field) parameter strongly related to soil moisture, a significant contribution from the μ (VH/VV_field) parameter strongly related to the dynamics of the vegetation cover, a strong contribution from the μ (NDVI_field) parameter related to the dynamics of the canopy, and to an important contribution from the μ (VV_5 km)/μ (VV_field) report, linked to the effect of irrigation at the plot scale compared with a larger scale dependent on precipitation events
The main objective of this study is to propose a mapping irrigation approach that is close to the operational approach
Summary
Water resource management is a key issue in climate change, considering the increasing number of drought events as well as the increase in water use for irrigation [1–6]. In this context, different decision tools have been developed to optimize water use for agriculture and irrigation [7–10]. One crucial question for managers is the precise identification of irrigated areas. Studies focused on the use of satellite imagery to identify irrigated areas. Different approaches were developed using optical data [16–28]. These included the use of Landsat data and more recently Sentinel-2 data. The detection principle is generally based on a vegetation index’s threshold as, on average, irrigated areas have a more developed vegetation cover
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