Differential Privacy of Quantum and Quantum-Inspired Classical Recommendation Algorithms
Abstract
We study the differential privacy (DP) of the quantum recommendation algorithm of Kerenidis--Prakash and its quantum-inspired classical counterpart. Under standard low-rank and incoherence assumptions on the preference matrix, we show that the randomness already present in the algorithms' measurement/2-sampling steps can act as a privacy-curating mechanism, yielding (,δ)-DP without injecting additional DP noise through the interface. Concretely, for a system with m users and n items and rank parameter k, we prove = O(k/n) and δ= O(k2/2\m,n\); in the typical regime k=polylog(m,n) this simplifies to = O(1/ n) and δ= O(1/2\m,n\). Our analysis introduces a perturbation technique for truncated SVD under a single-entry update, which tracks the induced change in the low-rank reconstruction while avoiding unstable singular-vector comparisons. Finally, we validate the scaling on real-world rating datasets and compare against classical DP recommender baselines.
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