New Lower Bounds for Private Estimation and a Generalized Fingerprinting Lemma

Kamath, Gautam; Mouzakis, Argyris; Singhal, Vikrant

doi:10.48550/arxiv.2205.08532

Cited by 3 publications

(5 citation statements)

References 11 publications

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“…Our lower bounds are loose in its dependence in log(1/δ). Recently, a promising lower bound technique has been introduced in [45] that might close this gap.…”

Section: Discussionmentioning

confidence: 99%

“…The next lower bound shows that without such assumptions on the tail, the error due to privacy scales as Ω( d ∧ log(1/δ)/(εn)). We believe that the dependence in δ is loose, and it might be possible to get a tighter lower bound using [45]. We provide a proof and other lower bounds in Appendix C.…”

Section: Differentially Private Principal Component Analysis (Dp-pca)mentioning

confidence: 99%

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DP-PCA: Statistically Optimal and Differentially Private PCA

Liu¹,

Kong²,

Jain³

et al. 2022

Preprint

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We study the canonical statistical task of computing the principal component from n i.i.d. data in d dimensions under (ε, δ)-differential privacy. Although extensively studied in literature, existing solutions fall short on two key aspects: (i) even for Gaussian data, existing private algorithms require the number of samples n to scale super-linearly with d, i.e., n = Ω(d 3/2 ), to obtain non-trivial results while non-private PCA requires only n = O(d), and (ii) existing techniques suffer from a non-vanishing error even when the randomness in each data point is arbitrarily small. We propose DP-PCA, which is a single-pass algorithm that overcomes both limitations. It is based on a private minibatch gradient ascent method that relies on private mean estimation, which adds minimal noise required to ensure privacy by adapting to the variance of a given minibatch of gradients. For sub-Gaussian data, we provide nearly optimal statistical error rates even for n = Õ(d). Furthermore, we provide a lower bound showing that sub-Gaussian style assumption is necessary in obtaining the optimal error rate.

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“…Our lower bounds are loose in its dependence in log(1/δ). Recently, a promising lower bound technique has been introduced in [45] that might close this gap.…”

Section: Discussionmentioning

confidence: 99%

Section: Differentially Private Principal Component Analysis (Dp-pca)mentioning

confidence: 99%

DP-PCA: Statistically Optimal and Differentially Private PCA

Liu¹,

Kong²,

Jain³

et al. 2022

Preprint

View full text Add to dashboard Cite

show abstract

“…However, the sample complexity of these methods depends on the condition number of the covariance matrix, and requires a priori bounds on the range of the parameters. The first finite sample complexity bound for privately learning unbounded Gaussians appeared in [AAK21], nearly matching the sample complexity lower bound of [KMS22]. The work of [AAK21] relies on 2 They assume there are known quantities R, σmax, σ min such that ∀i ∈…”

Section: Related Workmentioning

confidence: 99%

Polynomial Time and Private Learning of Unbounded Gaussian Mixture Models

Arbas¹,

Ashtiani²,

Liaw³

2023

Preprint

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We study the problem of privately estimating the parameters of d-dimensional Gaussian Mixture Models (GMMs) with k components. For this, we develop a technique to reduce the problem to its non-private counterpart. This allows us to privatize existing non-private algorithms in a blackbox manner, while incurring only a small overhead in the sample complexity and running time. As the main application of our framework, we develop an (ε, δ)-differentially private algorithm to learn GMMs using the non-private algorithm of Moitra and Valiant [MV10] as a blackbox. Consequently, this gives the first sample complexity upper bound and first polynomial time algorithm for privately learning GMMs without any boundedness assumptions on the parameters.

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“…d{nq (follows from the lower bound of mean estimation [KLSU19,BS16]) and an upper bound Õpd{nq (attained by the Gaussian mechanism). Very recently, Kamath et al [KMS22] improve the lower bound to r Ωpd{nq for d ă Op ? nq 2 , which means that the complexity of covariance estimation is same as d 2 -dimensional mean estimation in the low-dimensional regime, so one cannot hope to beat the Gaussian mechanism for small d. However, in the high-dimensional regime, our result indicates that the problem is strictly easier, due to the correlations of the d 2 entries of Σ.…”

Section: Worst-case Boundsmentioning

confidence: 99%

“…A Extend the lower bound from statistical setting to empirical setting [KMS22] considers the statistical setting where each X i " N p0, Σ D q with Ωp1q ¨I ď Σ D ď Op1q ¨I independently. In this case, we have }X i } 2 " Θp ?…”

Section: B Approximate Dp Error Bound For Emcovmentioning

confidence: 99%

Differentially Private Covariance Revisited

Wang¹,

Liang²,

Yi³

2022

Preprint

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In this paper, we present three new error bounds, in terms of the Frobenius norm, for covariance estimation under differential privacy: (1) a worst-case bound of Õpd 1{4 { ? nq, which improves the standard Gaussian mechanism Õpd{nq for the regime d ą r Ωpn 2{3 q;(2) a tracesensitive bound that improves the state of the art by a ? d-factor, and (3) a tail-sensitive bound that gives a more instance-specific result. The corresponding algorithms are also simple and efficient. Experimental results show that they offer significant improvements over prior work.

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New Lower Bounds for Private Estimation and a Generalized Fingerprinting Lemma

Cited by 3 publications

References 11 publications

DP-PCA: Statistically Optimal and Differentially Private PCA

DP-PCA: Statistically Optimal and Differentially Private PCA

Polynomial Time and Private Learning of Unbounded Gaussian Mixture Models

Differentially Private Covariance Revisited

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