Abstract
The availability of an unprecedented amount of open remote sensing data, such as Sentinel-1 and -2 data within the Copernicus program, has boosted the idea of combining the use of optical and radar data to improve the accuracy of agricultural applications such as crop classification. Sentinel-1’s Synthetic Aperture Radar (SAR) provides co- and cross-polarized backscatter, which offers the opportunity to monitor agricultural crops using radar at high spatial and temporal resolution. In this study, we assessed the potential of integrating Sentinel-1 information (VV and VH backscatter and their ratio VH/VV with Sentinel-2A data (NDVI) to perform crop classification and to define which are the most important input data that provide the most accurate classification results. Further, we examined the temporal dynamics of remote sensing data for cereal, horticultural, and industrial crops, perennials, deciduous trees, and legumes. To select the best SAR input feature, we tried two approaches, one based on classification with only SAR features and one based on integrating SAR with optical data. In total, nine scenarios were tested. Furthermore, we evaluated the performance of 22 nonparametric classifiers on which most of these algorithms had not been tested before with SAR data. The results revealed that the best performing scenario was the one integrating VH and VV with normalized difference vegetation index (NDVI) and cubic support vector machine (SVM) (the kernel function of the classifier is cubic) as the classifier with the highest accuracy among all those tested.
Highlights
Thanks to the development of Earth Observation (EO) technologies, remotely sensed data have become accessible for a broad range of users in both the public and private sector and cover many important application domains [1], such as protecting fragile ecosystems, managing climate risks, and enhancing food security [2]
Results show that Sentinel-1 cross-polarized VH backscattering coefficients have a strong vegetation contribution and are well correlated with the normalized difference vegetation index (NDVI) values retrieved from optical sensors, allow the extraction of meadow phenological phases
We evaluated the performance of 22 nonparametric classifiers with synthetic aperture radar (SAR)
Summary
Thanks to the development of Earth Observation (EO) technologies, remotely sensed data have become accessible for a broad range of users in both the public and private sector and cover many important application domains [1], such as protecting fragile ecosystems, managing climate risks, and enhancing food security [2]. Data derived from EO information are becoming indispensable in support of many sectors of society, especially for agronomic applications. Remote sensing data derived from EO have already proven their potential and effectiveness in spatiotemporal vegetation monitoring [3,4]; monitoring agricultural resources using remote sensing offers the opportunity to estimate crop areas [5], predict crop yield [6,7,8], and evaluate water demand [9,10] and to know the total surface that is cultivated and the precise distribution of crops [11]. The optical remote sensing methods used to assess crop status rely on combinations of different bands that are used to build relationships with crop
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