Optimal Quantum Differential Privacy via Fisher Information Spectral Analysis
Abstract
The Quantum Fisher Information (QFI) metric governs a fundamental duality: it quantifies both how precisely a parameter can be estimated (metrology) and how distinguishable two quantum states are (privacy). We exploit this duality to establish a geometry-aware framework for quantum differential privacy (DP) that replaces isotropic depolarizing noise with direction-dependent noise aligned to the QFI eigenstructure of the quantum embedding. We prove six principal theorems: (1) the minimax-optimal mechanism concentrates the noise budget in the dominant QFI eigenmode, achieving = (Δ2/2)λ(1-cγ) with O(d/λ) advantage; (2) mixed-state QFI decomposition reveals that dephasing in the adversary's basis increases accessible information, while misaligned-basis dephasing provides constructive privacy amplification from hardware noise; (3) a tight privacy - utility uncertainty relation · (1 - F) Δ22Tr(F)d; (4) adaptive QFI estimation converging at O(1/n) yields 1.92× tighter bounds; (5) QFI-aligned composition saturates at O(1) versus O(k) for standard composition; and (6) hardware noise can be harnessed for privacy amplification. Adversarial vulnerabilities, Wasserstein guarantees, subspace projection, and a zero-knowledge audit protocol follow as corollaries. Results are validated on Qiskit Aer GPU simulations, IBM Quantum hardware (ibmfez, 156 qubits), and against classical DP baselines, achieving equivalent utility at ≈ 0.001 versus ≈ 4800 for classical DP.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.