Abstract
Remote sensing image scene classification has a high application value in the agricultural, military, as well as other fields. A large amount of remote sensing data is obtained every day. After learning the new batch data, scene classification algorithms based on deep learning face the problem of catastrophic forgetting, that is, they cannot maintain the performance of the old batch data. Therefore, it has become more and more important to ensure that the scene classification model has the ability of continual learning, that is, to learn new batch data without forgetting the performance of the old batch data. However, the existing remote sensing image scene classification datasets all use static benchmarks and lack the standard to divide the datasets into a number of sequential learning training batches, which largely limits the development of continual learning in remote sensing image scene classification. First, this study gives the criteria for training batches that have been partitioned into three continual learning scenarios, and proposes a large-scale remote sensing image scene classification database called the Continual Learning Benchmark for Remote Sensing (CLRS). The goal of CLRS is to help develop state-of-the-art continual learning algorithms in the field of remote sensing image scene classification. In addition, in this paper, a new method of constructing a large-scale remote sensing image classification database based on the target detection pretrained model is proposed, which can effectively reduce manual annotations. Finally, several mainstream continual learning methods are tested and analyzed under three continual learning scenarios, and the results can be used as a baseline for future work.
Highlights
With the rapid development of remote sensing imaging technology, high-resolution remote sensing images are obtained and the interpretation of remote sensing images has evolved from the pixel- to the scene-level [1,2]
Due to the above problem, in this paper, we proposed a continual learning benchmark for remote sensing image scene classification, called Continual Learning Benchmark for Remote Sensing (CLRS, The dataset is available at https://github.com/lehaifeng/CLRS), to solve the limitations of existing datasets
The accuracy curves of the four methods all show an upward trend. This demonstrates that with different instances of the same scene category appearing in the subsequent training batches, the four methods can continuously refine and consolidate the knowledge of the category that has been learned
Summary
With the rapid development of remote sensing imaging technology, high-resolution remote sensing images are obtained and the interpretation of remote sensing images has evolved from the pixel- to the scene-level [1,2]. We focus on the problem of remote sensing image scene classification based on deep learning, which has been widely used in urban planning, disaster monitoring, and other fields, to provide a high-level interpretation ability for high-resolution remote sensing images. The existing classification algorithms, based on deep learning, assume that all of the training data were available before the training began. This is not realistic in real world remote sensing image. Haikel [8] proposed a framework for multitask learning that can learn from all available datasets
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