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RobQFL: Robust Quantum Federated Learning in Adversarial Environment

Quantum Physics 2025-09-08 v1 Machine Learning

Abstract

Quantum Federated Learning (QFL) merges privacy-preserving federation with quantum computing gains, yet its resilience to adversarial noise is unknown. We first show that QFL is as fragile as centralized quantum learning. We propose Robust Quantum Federated Learning (RobQFL), embedding adversarial training directly into the federated loop. RobQFL exposes tunable axes: client coverage γ\gamma (0-100\%), perturbation scheduling (fixed-ε\varepsilon vs ε\varepsilon-mixes), and optimization (fine-tune vs scratch), and distils the resulting γ×ε\gamma \times \varepsilon surface into two metrics: Accuracy-Robustness Area and Robustness Volume. On 15-client simulations with MNIST and Fashion-MNIST, IID and Non-IID conditions, training only 20-50\% clients adversarially boosts ε0.1\varepsilon \leq 0.1 accuracy \sim15 pp at <2< 2 pp clean-accuracy cost; fine-tuning adds 3-5 pp. With \geq75\% coverage, a moderate ε\varepsilon-mix is optimal, while high-ε\varepsilon schedules help only at 100\% coverage. Label-sorted non-IID splits halve robustness, underscoring data heterogeneity as a dominant risk.

Keywords

Cite

@article{arxiv.2509.04914,
  title  = {RobQFL: Robust Quantum Federated Learning in Adversarial Environment},
  author = {Walid El Maouaki and Nouhaila Innan and Alberto Marchisio and Taoufik Said and Muhammad Shafique and Mohamed Bennai},
  journal= {arXiv preprint arXiv:2509.04914},
  year   = {2025}
}
R2 v1 2026-07-01T05:22:45.467Z