Fourier Sparse Leverage Scores and Approximate Kernel Learning

TL;DR

This paper establishes new bounds on Fourier sparse leverage scores under Gaussian and Laplace measures, enabling improved kernel approximation and active learning methods for low-dimensional data.

Contribution

It introduces explicit upper bounds on Fourier sparse leverage scores and applies these bounds to develop novel kernel approximation and active learning algorithms.

Findings

New bounds on Fourier sparse leverage scores under Gaussian and Laplace measures.

A near optimal random Fourier features algorithm for kernel approximation.

Enhanced active learning strategies for Gaussian and Laplace distributed data.

Abstract

We prove new explicit upper bounds on the leverage scores of Fourier sparse functions under both the Gaussian and Laplace measures. In particular, we study $s$-sparse functions of the form $f(x) = \sum_{j=1}^s a_j e^{i \lambda_j x}$ for coefficients $a_j \in \mathbb{C}$ and frequencies $\lambda_j \in \mathbb{R}$. Bounding Fourier sparse leverage scores under various measures is of pure mathematical interest in approximation theory, and our work extends existing results for the uniform measure [Erd17,CP19a]. Practically, our bounds are motivated by two important applications in machine learning: 1. Kernel Approximation. They yield a new random Fourier features algorithm for approximating Gaussian and Cauchy (rational quadratic) kernel matrices. For low-dimensional data, our method uses a near optimal number of features, and its runtime is polynomial in the $statistical\ dimension$ of the approximated kernel matrix. It is the first "oblivious sketching method" with this property for any kernel besides the polynomial kernel, resolving an open question of [AKM+17,AKK+20b]. 2. Active Learning. They can be used as non-uniform sampling distributions for robust active learning when data follows a Gaussian or Laplace distribution. Using the framework of [AKM+19], we provide essentially optimal results for bandlimited and multiband interpolation, and Gaussian process regression. These results generalize existing work that only applies to uniformly distributed data.