Fast Private Kernel Density Estimation via Locality Sensitive Quantization
We study efficient mechanisms for differentially private kernel density estimation (DP-KDE). Prior work for the Gaussian kernel described algorithms that run in time exponential in the number of dimensions $d$. This paper breaks the exponential barrier, and shows how the KDE can privately be approxi...
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Zusammenfassung: | We study efficient mechanisms for differentially private kernel density
estimation (DP-KDE). Prior work for the Gaussian kernel described algorithms
that run in time exponential in the number of dimensions $d$. This paper breaks
the exponential barrier, and shows how the KDE can privately be approximated in
time linear in $d$, making it feasible for high-dimensional data. We also
present improved bounds for low-dimensional data.
Our results are obtained through a general framework, which we term Locality
Sensitive Quantization (LSQ), for constructing private KDE mechanisms where
existing KDE approximation techniques can be applied. It lets us leverage
several efficient non-private KDE methods -- like Random Fourier Features, the
Fast Gauss Transform, and Locality Sensitive Hashing -- and ``privatize'' them
in a black-box manner. Our experiments demonstrate that our resulting DP-KDE
mechanisms are fast and accurate on large datasets in both high and low
dimensions. |
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DOI: | 10.48550/arxiv.2307.01877 |