Optimal QLDP mechanisms achieve the same asymptotic Q/C ratio as classical LDP for Holevo information and hypothesis-testing error exponents, with Q/C >= 3/2 when protecting n-ary data for n >= 3.
Mutual Information Optimally Local Private Discrete Distribution Estimation
2 Pith papers cite this work. Polarity classification is still indexing.
abstract
Consider statistical learning (e.g. discrete distribution estimation) with local $\epsilon$-differential privacy, which preserves each data provider's privacy locally, we aim to optimize statistical data utility under the privacy constraints. Specifically, we study maximizing mutual information between a provider's data and its private view, and give the exact mutual information bound along with an attainable mechanism: $k$-subset mechanism as results. The mutual information optimal mechanism randomly outputs a size $k$ subset of the original data domain with delicate probability assignment, where $k$ varies with the privacy level $\epsilon$ and the data domain size $d$. After analysing the limitations of existing local private mechanisms from mutual information perspective, we propose an efficient implementation of the $k$-subset mechanism for discrete distribution estimation, and show its optimality guarantees over existing approaches.
years
2026 2verdicts
UNVERDICTED 2representative citing papers
QIF framework using Blackwell ordering classifies seven LDP frequency estimation protocols and shows some previously optimal ones are incomparable or strictly dominated.
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Optimal quantum locally differentially private mechanisms in the high-privacy regime
Optimal QLDP mechanisms achieve the same asymptotic Q/C ratio as classical LDP for Holevo information and hypothesis-testing error exponents, with Q/C >= 3/2 when protecting n-ary data for n >= 3.
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Beyond Epsilon: A Principled QIF Framework for Local Differential Privacy
QIF framework using Blackwell ordering classifies seven LDP frequency estimation protocols and shows some previously optimal ones are incomparable or strictly dominated.