Abstract

Mapping irrigated plots is essential for better water resource management. Today, the free and open access Sentinel-1 (S1) and Sentinel-2 (S2) data with high revisit time offers a powerful tool for irrigation mapping at plot scale. Up to date, few studies have used S1 and S2 data to provide approaches for mapping irrigated plots. This study proposes a method to map irrigated plots using S1 SAR (synthetic aperture radar) time series. First, a dense temporal series of S1 backscattering coefficients were obtained at plot scale in VV (Vertical-Vertical) and VH (Vertical-Horizontal) polarizations over a study site located in Catalonia, Spain. In order to remove the ambiguity between rainfall and irrigation events, the S1 signal obtained at plot scale was used conjointly to S1 signal obtained at a grid scale (10 km × 10 km). Later, two mathematical transformations, including the principal component analysis (PCA) and the wavelet transformation (WT), were applied to the several SAR temporal series obtained in both VV and VH polarization. Irrigated areas were then classified using the principal component (PC) dimensions and the WT coefficients in two different random forest (RF) classifiers. Another classification approach using one dimensional convolutional neural network (CNN) was also performed on the obtained S1 temporal series. The results derived from the RF classifiers with S1 data show high overall accuracy using the PC values (90.7%) and the WT coefficients (89.1%). By applying the CNN approach on SAR data, a significant overall accuracy of 94.1% was obtained. The potential of optical images to map irrigated areas by the mean of a normalized differential vegetation index (NDVI) temporal series was also tested in this study in both the RF and the CNN approaches. The overall accuracy obtained using the NDVI in RF classifier reached 89.5% while that in the CNN reached 91.6%. The combined use of optical and radar data slightly enhanced the classification in the RF classifier but did not significantly change the accuracy obtained in the CNN approach using S1 data.

Highlights

  • Under changing climatic conditions, irrigation plays a significant role in agricultural production in order to meet the global food requirement

  • Using the conserved important variables in both methods, the accuracy slightly decreased compared to that obtained using all variables

  • To remove the ambiguity between rainfall and irrigation events, the S1 signal at plot scale was compared to that obtained at grid scale (10 km × 10 km)

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Summary

Introduction

Irrigation plays a significant role in agricultural production in order to meet the global food requirement. Chen et al [18] proposed a new approach to map irrigation extent, time and frequency in an arid region located in Hexi Corridor of northwest China by merging the 30 m spatial resolution Landsat images with 250 m MODIS data and ancillary data. In their study, they used the GI to detect irrigation events during the first half of the growing season. The two classification approaches (RF and CNN) were inter-compared

Study Site
Sentinel-1 SAR Data
Sentinel-2 Optical Data
Overview
NDVI Temporal Series at Plot Scale
Haar Wavelet Transformation
Random Forest Classifier
Convolutional Neural Network
Accuracy Assesment
Method
NDVI-RF
RF Using Combined Optical and SAR Data
CNN on SAR Temporal Series
CNN Using NDVI Temporal Series
CNN Using Combined SAR and Optical Data
Irrigation Mapping
CNN Approach
Inter-Comparison and Quality Assessment
Findings
Conclusions

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