Differentially Private Inference for Binomial Data

Awan, Jordan; Slavković, Aleksandra

doi:10.29012/jpc.725

Cited by 29 publications

(60 citation statements)

References 23 publications

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“…Perhaps most relevant to this work are Cai et al (2017); Acharya et al (2018b); Aliakbarpour et al (2018), which study the sample complexity of differentially privately performing classical distribution testing problems, including identity and closeness testing. Some recent work focuses on the testing of simple hypotheses: Canonne et al (2019) studies the sample complexity of this problem, while Awan and Slavkovic (2018) provides a uniformly most powerful (UMP) test for binomial data (though Brenner and Nissim (2014) shows that UMP tests can not exist in general). Other works investigating private hypothesis testing include Wang et al (2015a); Gaboardi et al (2016); Kifer and Rogers (2017); Kakizaki et al (2017); ; Campbell et al (2018); Swanberg et al (2019); Couch et al (2019), which focus less on characterizing the finite-sample guarantees of such tests, and more on understanding their asymptotic properties and applications to computing p-values.…”

Section: Introductionmentioning

confidence: 99%

INSPECTRE: Privately Estimating the Unseen

Acharya¹,

Kamath²,

Sun³

et al. 2020

JPC

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We develop differentially private methods for estimating various distributional properties. Given a sample from a discrete distribution p, some functional f, and accuracy and privacy parameters alpha and epsilon, the goal is to estimate f(p) up to accuracy alpha, while maintaining epsilon-differential privacy of the sample. We prove almost-tight bounds on the sample size required for this problem for several functionals of interest, including support size, support coverage, and entropy. We show that the cost of privacy is negligible in a variety of settings, both theoretically and experimentally. Our methods are based on a sensitivity analysis of several state-of-the-art methods for estimating these properties with sublinear sample complexities

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Section: Introductionmentioning

confidence: 99%

INSPECTRE: Privately Estimating the Unseen

Acharya¹,

Kamath²,

Sun³

et al. 2020

JPC

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“…Despite the preponderance of differentially private algorithms applicable to point estimation, only recently have studies begun to address other aspects of statistical inference, namely, confidence intervals and hypothesis testing. Several studies have developed differentially private tests for simple models, including for the mean of a normal distribution (Solea, 2014), the difference between means (D'orazio et al , 2015), the independent samples t ‐test (Ding et al , 2018), the Wilcoxon signed‐rank test (Couch et al , 2018; Task & Clifton, 2016) and the binomial test (Awan & Slavkovic, 2018; Vu & Slavkovic, 2009). Differentially private confidence intervals for the mean of a normal distribution were developed by Karwa & Vadhan (2017).…”

Section: Confidence Intervals and Hypothesis Testsmentioning

confidence: 99%

A Survey of Differentially Private Regression for Clinical and Epidemiological Research

Ficek

Wang

Chen

et al. 2020

Int Statistical Rev

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Summary Differential privacy is a framework for data analysis that provides rigorous privacy protections for database participants. It has increasingly been accepted as the gold standard for privacy in the analytics industry, yet there are few techniques suitable for statistical inference in the health sciences. This is notably the case for regression, one of the most widely used modelling tools in clinical and epidemiological studies. This paper provides an overview of differential privacy and surveys the literature on differentially private regression, highlighting the techniques that hold the most relevance for statistical inference as practiced in clinical and epidemiological research. Research gaps and opportunities for further inquiry are identified.

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“…That is, the advantage of the optimal tester must be matched by some coupling of P n and Q n . [AS18] gives a universally optimal test when the domain size is two, however Brenner and Nissim [BN14] shows that such universally optimal tests cannot exist when the domain has more than two elements. A complementary research direction, initiated by Cai et al [CDK17], studies the minimax sample complexity of private hypothesis testing.…”

Section: Techniquesmentioning

confidence: 99%

The structure of optimal private tests for simple hypotheses

Canonne

Kamath

McMillan

et al. 2019

Proceedings of the 51st Annual ACM SIGACT Symposium on Theory of Computing

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Hypothesis testing plays a central role in statistical inference, and is used in many settings where privacy concerns are paramount. This work answers a basic question about privately testing simple hypotheses: given two distributions P and Q, and a privacy level ε, how many i.i.d. samples are needed to distinguish P from Q subject to ε-differential privacy, and what sort of tests have optimal sample complexity? Specifically, we characterize this sample complexity up to constant factors in terms of the structure of P and Q and the privacy level ε, and show that this sample complexity is achieved by a certain randomized and clamped variant of the log-likelihood ratio test. Our result is an analogue of the classical Neyman-Pearson lemma in the setting of private hypothesis testing. We also give an application of our result to private change-point detection. Our characterization applies more generally to hypothesis tests satisfying essentially any notion of algorithmic stability, which is known to imply strong generalization bounds in adaptive data analysis, and thus our results have applications even when privacy is not a primary concern.

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Differentially Private Inference for Binomial Data

Cited by 29 publications

References 23 publications

INSPECTRE: Privately Estimating the Unseen

INSPECTRE: Privately Estimating the Unseen

A Survey of Differentially Private Regression for Clinical and Epidemiological Research

The structure of optimal private tests for simple hypotheses

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