Input-Aware Dynamic Backdoor Attack Against Quantum Neural Networks
2026-07-13 • Machine Learning
Machine Learning
AI summaryⓘ
The authors studied security risks in Quantum Neural Networks (QNNs), which are quantum versions of neural networks. They found that past attacks used the same fixed trigger for backdoors, making them easier to detect. To improve this, the authors developed Q-DIBA, a new attack that uses input-aware dynamic triggers that adapt based on the input, making it harder to spot. They tested Q-DIBA on common image datasets and found it works well while being hard to defend against, revealing a new security challenge for quantum machine learning.
Quantum Neural NetworksBackdoor AttackDynamic BackdoorTrigger GeneratorDensity MatrixContrastive LearningAnsatzQuantum MeasurementSpectral-Signature DetectionFine-Tuning Defense
Authors
Junrui Zhang, Zemin Chen, Lusi Li, Mohammad Ghasemigol, Daniel Takabi, Rui Ning
Abstract
Quantum Neural Networks (QNNs) are a promising framework for quantum machine learning on near-term quantum devices, but their security risks remain insufficiently understood. Studies have shown that QNNs are vulnerable to backdoor attacks, yet existing quantum backdoors mostly rely on a fixed trigger shared by all poisoned inputs. This fixed-trigger design is a major weakness because many defenses detect or weaken the repeated patterns such triggers leave in data representations. Although input-aware dynamic backdoors have been studied in classical neural networks, transferring them to QNNs is difficult because quantum learning introduces new obstacles. In particular, measurement compresses the post-ansatz quantum state into a limited classical output, weakening supervision for a trigger generator, while individual density matrices fluctuate with the input and make per-sample contrastive learning unstable. To address these challenges, we propose Q-DIBA, the first input-aware dynamic backdoor attack for QNNs. Q-DIBA jointly trains a classical trigger generator and a victim QNN through a three-mode mini-batch strategy that supports clean behavior, attack activation, and trigger specificity. To provide stable quantum-level supervision, Q-DIBA introduces an ensemble density contrastive loss that operates on post-ansatz quantum states before measurement and contrasts mode-averaged density matrices rather than individual samples. Experiments on MNIST and Fashion-MNIST across multiple QNN architectures show that Q-DIBA achieves high clean accuracy, strong attack success, and high cross-trigger accuracy, demonstrating effectiveness, stealthiness, and input specificity. The attack also remains resilient against defenses including visual inspection, spectral-signature detection, and fine-tuning, suggesting that input-aware quantum backdoors are an important threat to secure QNN deployment.