Sparsifying Suprema of Gaussian Processes

We give a dimension-independent sparsification result for suprema of centered Gaussian processes: Let $T$ be any (possibly infinite) bounded set of vectors in $\mathbb{R}^n$, and let $\{\boldsymbol{X}_t := t \cdot \boldsymbol{g} \}_{t\in T}$ be the canonical Gaussian process on $T$, where $\boldsymbol{g}\sim N(0, I_n)$. We show that there is an $O_\varepsilon(1)$-size subset $S \subseteq T$ and a set of real values $\{c_s\}_{s \in S}$ such that the random variable $\sup_{s \in S} \{\boldsymbol{X}_s + c_s\}$ is an $\varepsilon$-approximator\,(in $L^1$) of the random variable $\sup_{t \in T} {\boldsymbol{X}}_t$. Notably, the size of the sparsifier $S$ is completely independent of both $|T|$ and the ambient dimension $n$.We give two applications of this sparsification theorem:- A "Junta Theorem" for Norms: We show that given any norm $\nu(x)$ on $\mathbb{R}^n$, there is another norm $\psi(x)$ depending only on the projection of $x$ onto $O_\varepsilon(1)$ directions, for which $\psi({\boldsymbol{g}})$ is a multiplicative $(1 \pm \varepsilon)$-approximation of $\nu({\boldsymbol{g}})$ with probability $1-\varepsilon$ for ${\boldsymbol{g}} \sim N(0,I_n)$.- Sparsification of Convex Sets: We show that any intersection of (possibly infinitely many) halfspaces in $\mathbb{R}^n$ that are at distance $r$ from the origin is $\varepsilon$-close (under $N(0,I_n)$) to an intersection of only $O_{r,\varepsilon}(1)$ halfspaces. This yields new polynomial-time \emph{agnostic learning} and \emph{tolerant property testing} algorithms for intersections of halfspaces.