Abstract

Abstract. Transfer learning methods reuse a deep learning model developed for a task on another task. Such methods have been remarkably successful in a wide range of image processing applications. Following the trend, few transfer learning based methods have been proposed for unsupervised multi-temporal image analysis and change detection (CD). Inspite of their success, the transfer learning based CD methods suffer from limited explainability. In this paper, we propose an explainable convolutional autoencoder model for CD. The model is trained in: 1) an unsupervised way using, as the bi-temporal images, patches extracted from the same geographic location; 2) a greedy fashion, one encoder and decoder layer pair at a time. A number of features relevant for CD is chosen from the encoder layer. To build an explainable model, only selected features from the encoder layer is retained and the rest is discarded. Following this, another encoder and decoder layer pair is added to the model in similar fashion until convergence. We further visualize the features to better interpret the learned features. We validated the proposed method on a Landsat-8 dataset obtained in Spain. Using a set of experiments, we demonstrate the explainability and effectiveness of the proposed model.

Highlights

  • Multi-temporal image analysis is one of the most popular research topics in remote sensing

  • We proposed an explainable convolutional autoencoder (CAE) model for unsupervised change detection

  • While the proposed method takes advantage of transfer learning by learning to reconstruct a dataset of patches, the learned features are further selected based on a standard-deviation criterion after each layer is trained

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Summary

Introduction

Multi-temporal image analysis is one of the most popular research topics in remote sensing. In the last 15 years, many new satellite based sensors have been launched by space agencies, increasing the number of available sensors periodically orbiting the Earth. Images are available from different imaging modalities (passive/active) and different spectral, spatial, and temporal resolutions (Bovolo, Bruzzone, 2015). This has resulted in strong increase in development of novel multi-temporal image analysis methods, especially aiming towards unsupervised Change Detection (CD) (Celik, 2009) (Bovolo, Bruzzone, 2015). The unsupervised CD methods in the literature often need to be largely modified to account for differences in acquisition sensor and resolution (Bovolo, Bruzzone, 2015)

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