Bullseye Polytope: A Scalable Clean-Label Poisoning Attack with Improved Transferability
May 01, 2020 ยท Declared Dead ยท ๐ European Symposium on Security and Privacy
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Authors
Hojjat Aghakhani, Dongyu Meng, Yu-Xiang Wang, Christopher Kruegel, Giovanni Vigna
arXiv ID
2005.00191
Category
cs.LG: Machine Learning
Cross-listed
cs.CR,
stat.ML
Citations
123
Venue
European Symposium on Security and Privacy
Last Checked
4 months ago
Abstract
A recent source of concern for the security of neural networks is the emergence of clean-label dataset poisoning attacks, wherein correctly labeled poison samples are injected into the training dataset. While these poison samples look legitimate to the human observer, they contain malicious characteristics that trigger a targeted misclassification during inference. We propose a scalable and transferable clean-label poisoning attack against transfer learning, which creates poison images with their center close to the target image in the feature space. Our attack, Bullseye Polytope, improves the attack success rate of the current state-of-the-art by 26.75% in end-to-end transfer learning, while increasing attack speed by a factor of 12. We further extend Bullseye Polytope to a more practical attack model by including multiple images of the same object (e.g., from different angles) when crafting the poison samples. We demonstrate that this extension improves attack transferability by over 16% to unseen images (of the same object) without using extra poison samples.
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