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Locally Differentially-Private Randomized Response for Discrete Distribution Learning

Machine Learning 2018-11-30 v1 Information Theory math.IT Machine Learning

Abstract

We consider a setup in which confidential i.i.d. samples X1,,XnX_1,\dotsc,X_n from an unknown finite-support distribution p\boldsymbol{p} are passed through nn copies of a discrete privatization channel (a.k.a. mechanism) producing outputs Y1,,YnY_1,\dotsc,Y_n. The channel law guarantees a local differential privacy of ϵ\epsilon. Subject to a prescribed privacy level ϵ\epsilon, the optimal channel should be designed such that an estimate of the source distribution based on the channel outputs Y1,,YnY_1,\dotsc,Y_n converges as fast as possible to the exact value p\boldsymbol{p}. For this purpose we study the convergence to zero of three distribution distance metrics: ff-divergence, mean-squared error and total variation. We derive the respective normalized first-order terms of convergence (as nn\to\infty), which for a given target privacy ϵ\epsilon represent a rule-of-thumb factor by which the sample size must be augmented so as to achieve the same estimation accuracy as that of a non-randomizing channel. We formulate the privacy-fidelity trade-off problem as being that of minimizing said first-order term under a privacy constraint ϵ\epsilon. We further identify a scalar quantity that captures the essence of this trade-off, and prove bounds and data-processing inequalities on this quantity. For some specific instances of the privacy-fidelity trade-off problem, we derive inner and outer bounds on the optimal trade-off curve.

Keywords

Cite

@article{arxiv.1811.12257,
  title  = {Locally Differentially-Private Randomized Response for Discrete Distribution Learning},
  author = {Adriano Pastore and Michael Gastpar},
  journal= {arXiv preprint arXiv:1811.12257},
  year   = {2018}
}

Comments

47 pages, under revision at JMLR

R2 v1 2026-06-23T06:25:26.296Z