Abstract

The objective of this work is to evaluate the capacity of the C-band Synthetic Aperture Radar (SAR) time series imagery, acquired by the European satellite Sentinel-1 (S1), for the agriculture crop classification and its reliability to differentiate onion from sunflower, among others. The work then focused on classifying land cover in intensively cultivated agricultural regions. The study was developed in the Bonaerense Valley of the Colorado River (BVCR), Buenos Aires Province in Argentina, backed up by the field truth of 1634 field samples. In addition to the onion and sunflower crops, there are other crops present in the study area such as cereals, alfalfa, potatoes and maize, which are considered as the image background in the classification process. The field samples database was used for training and supporting a supervised classification with two machine learning algorithms—Random Forest (RF) and Support Vector Machine (SVM)—obtaining high levels of accuracy in each case. Different S1 SAR time-series features were used to assess the performance of S1 crop classification in terms of polarization VH+VV, Grey Level Co-occurrence Matrix (GLCM) image texture and a combination of both. The analysis of SAR data and their features was carried out at OBIA lot level (Object Based Image Analysis) showing an optimal strategy to counteract the effect of the residual and inherent speckle noise of the radar signal. In the process of differentiating onion and sunflower crops, the analysis of the VH+VV stack with the SVM algorithm delivered the best statistical classification results in terms of Overall Accuracy (OA) and Kappa Index, (Kp) when other crops (image background) were not considered (OA = 95.35%, Kp = 0.89). Certainly, the GLCM texture analysis derived from the S1 SAR images is a valuable source of information for obtaining very good classification results. When differentiating sunflower from onion considering also other crops present in the BVCR, the GLCM stack proved to be the most suitable dataset analyzed in this work (OA = 89.98%, Kp = 0.66 for SVM algorithm). This working methodology is applicable to other irrigated valleys in Argentina dedicated to intensive crops. There are also variables inherent to each lot, soil, crop and agricultural producer that differ according to the study area and that should be considered for each case in the future.

Highlights

  • Irrigated valleys represent only 20% of the world’s cropland, but on the other hand, they produce40% of the global crop harvest

  • The Bonaerense Valley of Colorado River (BVCR) is an irrigated cultivated area located in the south of Buenos Aires Province, Argentina

  • We evaluated two machine learning algorithms, Random Forest (RF) and Support Vector Machine (SVM), for discriminating land cover types

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Summary

Introduction

Irrigated valleys represent only 20% of the world’s cropland, but on the other hand, they produce40% of the global crop harvest. The amount of water for irrigation purposes as well as for the crops yield and the size of the cultivated areas must be determined in order to estimate the available food for all humankind [2]. Among different crops present in the area, onion and sunflower have a high regional economy impact with thousands of cultivated hectares. Due to this economic significance and the objective of maximizing the efficiency of agriculture activities using good agronomic practices, it is crucial to know—as precisely as possible—the cultivated area size and the spatial distribution in order to manage the natural resources properly.

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