Project Gradient Descent Adversarial Attack against Multisource Remote Sensing Image Scene Classification

Deep learning technology (a deeper and optimized network structure) and remote sensing imaging (i.e., the moremultisource and the more multicategory remote sensing data) have developed rapidly. Although the deep convolutional neural network (CNN) has achieved state-of-the-art performance on remote sensing image (RSI) scene classification, the existence of adversarial attacks poses a potential security threat to the RSI scene classification task based on CNN. (e corresponding adversarial samples can be generated by adding a small perturbation to the original images. Feeding the CNN-based classifier with the adversarial samples leads to the classifier misclassify with high confidence. To achieve a higher attack success rate against scene classification based on CNN, we introduce the projected gradient descent method to generate adversarial remote sensing images. (en, we select several mainstream CNN-based classifiers as the attacked models to demonstrate the effectiveness of our method. (e experimental results show that our proposed method can dramatically reduce the classification accuracy under untargeted and targeted attacks. Furthermore, we also evaluate the quality of the generated adversarial images by visual and quantitative comparisons. (e results show that our method can generate the imperceptible adversarial samples and has a stronger attack ability for the RSI scene classification.

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