We consider a random variable $X$ that takes values in a (possibly
infinite-dimensional) topological vector space $\mathcal{X}$. We show that,
with respect to an appropriate "normal distance" on $\mathcal{X}$,
concentration inequalities for linear and non-linear functions of $X$ are
equivalent. This normal distance corresponds naturally to the concentration
rate in classical concentration results such as Gaussian concentration and
concentration on the Euclidean and Hamming cubes. Under suitable assumptions on
the roundness of the sets of interest, the concentration inequalities so
obtained are asymptotically optimal in the high-dimensional limit.Comment: 19 pages, 5 figure

Owhadi, Houman

Sullivan, Timothy John

English

arXiv

We consider a random variable X that takes values in a (possibly infinite-dimensional) topological vector space X. We show that, with respect to an appropriate "normal distance" on X, concentration inequalities for linear and non-linear functions of X are equivalent. This normal distance corresponds naturally to the concentration rate in classical concentration results such as Gaussian concentration and concentration on the Euclidean and Hamming cubes. Under suitable assumptions on the roundness of the sets of interest, the concentration inequalities so obtained are asymptotically optimal in the high-dimensional limit

Sullivan, T. J.

Owhadi, H.

Caltech Authors - Main

Equivalence of concentration inequalities for linear and non-linear functions

http://authors.library.caltech.edu/64721/1/1009.4913.pdf

Equivalence of concentration inequalities for linear and non-linear functions

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Caltech Authors - Main

Caltech Authors - Main