Abstract
In previous studies, parameters derived from polarimetric target decompositions have proven as very effective features for crop classification with single/multi-temporal polarimetric synthetic aperture radar (PolSAR) data. In particular, a classical eigenvalue-eigenvector-based decomposition approach named after Cloude–Pottier decomposition (or “H/A/α”) has been frequently used to construct classification approaches. A model-based decomposition approach proposed by Neumann some years ago provides two parameters with very similar physical meanings to polarimetric scattering entropy H and the alpha angle α in Cloude–Pottier decomposition. However, the main aim of the Neumann decomposition is to describe the morphological characteristics of vegetation. Therefore, it is worth investigating the performance of Neumann decomposition on crop classification, since vegetation is the principal type of targets in agricultural scenes. In this paper, a multi-temporal supervised classification method based on Neumann decomposition and Random Forest Classifier (named “ND-RF”) is proposed. The three parameters from Neumann decomposition, computed along the time series of data, are used as classification features. Finally, the Random Forest Classifier is applied for supervised classification. For comparison, an analogue classification scheme is constructed by replacing the Neumann decomposition with the Cloude–Pottier decomposition, hence named CP-RF. For validation, a time series of 11 polarimetric RADARSAT-2 SAR images acquired over an agricultural site in London, Ontario, Canada in 2015 is employed. Totally, 10 multi-temporal combinations of datasets were tested by adding images one by one sequentially along the SAR observation time. The results show that the ND-RF method generally produces better classification performance than the CP-RF method, with the largest improvement of over 12% in overall accuracy. Further tests show that the two parameters similar to entropy and alpha angle produce classification results close to those of CP-RF, whereas the third parameter in the Neumann decomposition is more effective in improving the classification accuracy with respect to the Cloude–Pottier decomposition.
Highlights
Crops play an essential role in global economic activity, diets, biofuel and climate change [1]
A multi-temporal supervised classification method based on Neumann decomposition and Random Forest Classifier for crop classification is proposed in this paper
The Neumann decomposition is aimed at describing vegetation scattering, and two of its output parameters have physical meanings close to Cloude–Pottier decomposition outputs
Summary
Crops play an essential role in global economic activity, diets, biofuel and climate change [1]. The Cloude–Pottier decomposition is the most representative method in this category [4,34] Based on this decomposition, three polarimetric parameters with clear physical interpretations, including the polarimetric scattering entropy H, the alpha angle α and the polarimetric anisotropy A are derived. Multi-temporal data usually show stronger ability to discriminate different crop types than single-date data Based on these motivations, a multi-temporal supervised classification method based on Neumann decomposition and Random Forest Classifier (named as “ND-RF”) for crop classification is proposed in this paper. A multi-temporal supervised classification method based on Neumann decomposition and Random Forest Classifier (named as “ND-RF”) for crop classification is proposed in this paper In this approach, the Neumann decomposition is used for providing three polarimetric parameters (|δ|, τ, φδ) as classification features.
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