Invisible Backdoor Attack with Sample-Specific Triggers
This work addresses the vulnerability of deep neural networks to backdoor attacks, posing a security threat to users who rely on these models, by introducing a more stealthy and robust attack mechanism.
This paper introduces a novel backdoor attack where triggers are sample-specific and invisible, generated by encoding a string into benign images as additive noise. The attacked model performs well on benign samples but misclassifies samples with the activated backdoor, demonstrating effectiveness against models with and without defenses.
Recently, backdoor attacks pose a new security threat to the training process of deep neural networks (DNNs). Attackers intend to inject hidden backdoors into DNNs, such that the attacked model performs well on benign samples, whereas its prediction will be maliciously changed if hidden backdoors are activated by the attacker-defined trigger. Existing backdoor attacks usually adopt the setting that triggers are sample-agnostic, $i.e.,$ different poisoned samples contain the same trigger, resulting in that the attacks could be easily mitigated by current backdoor defenses. In this work, we explore a novel attack paradigm, where backdoor triggers are sample-specific. In our attack, we only need to modify certain training samples with invisible perturbation, while not need to manipulate other training components ($e.g.$, training loss, and model structure) as required in many existing attacks. Specifically, inspired by the recent advance in DNN-based image steganography, we generate sample-specific invisible additive noises as backdoor triggers by encoding an attacker-specified string into benign images through an encoder-decoder network. The mapping from the string to the target label will be generated when DNNs are trained on the poisoned dataset. Extensive experiments on benchmark datasets verify the effectiveness of our method in attacking models with or without defenses.