Learning set functions is a key challenge arising in many domains, ranging from sketching graphs to black-box optimization with discrete parameters. In this paper we consider the problem of efficiently learning set functions that are defined over a ground set of size n and that are sparse (say k-sparse) in the Fourier domain. This is a wide class, that includes graph and hypergraph cut functions, decision trees and more. Our central contribution is the first algorithm that allows learning functions whose Fourier support only contains low degree (say degree d = o(n)) polynomials using O(kd log n) sample complexity and runtime O(kn log(2) k log n log d). This implies that sparse graphs with k edges can, for the first time, be learned from O(k...
Given an n-length input signal x, it is well known that its Discrete Fourier Transform (DFT), X, can...
Abstract. We present a range of new results for testing properties of Boolean functions that are def...
A function defined on the Boolean hypercube is k-Fourier-sparse if it has at most k nonzero Fourier ...
Can we learn a sparse graph from observing the value of a few random cuts? This and more general pro...
Many applications of machine learning on discrete domains, such as learning preference functions in ...
Abstract. This work gives a polynomial time algorithm for learning decision trees with respect to th...
Abstract—Given an n-length input signal x, it is well known that its Discrete Fourier Transform (DFT...
The topic of discrete Fourier analysis has been extensively studied in recent decades. It plays an i...
We consider the problem of computing a k-sparse approximation to the discrete Fourier transform of a...
We consider the problem of computing a k-sparse approximation to the discrete Fourier trans-form of ...
In this paper, we explore the topic of graph learning from the perspective of the Irregularity-Aware...
ABSTRACT We give an algorithm for finding a Fourier representation R of B terms for a given discrete...
Abstract. We present a range of new results for testing properties of Boolean functions that are def...
A. C. Gilbert S. Guha P. Indyk S. Muthukrishnan M. Strauss ABSTRACT We give an algorit...
This thesis focuses on developing efficient algorithmic tools for processing large datasets. In many...
Given an n-length input signal x, it is well known that its Discrete Fourier Transform (DFT), X, can...
Abstract. We present a range of new results for testing properties of Boolean functions that are def...
A function defined on the Boolean hypercube is k-Fourier-sparse if it has at most k nonzero Fourier ...
Can we learn a sparse graph from observing the value of a few random cuts? This and more general pro...
Many applications of machine learning on discrete domains, such as learning preference functions in ...
Abstract. This work gives a polynomial time algorithm for learning decision trees with respect to th...
Abstract—Given an n-length input signal x, it is well known that its Discrete Fourier Transform (DFT...
The topic of discrete Fourier analysis has been extensively studied in recent decades. It plays an i...
We consider the problem of computing a k-sparse approximation to the discrete Fourier transform of a...
We consider the problem of computing a k-sparse approximation to the discrete Fourier trans-form of ...
In this paper, we explore the topic of graph learning from the perspective of the Irregularity-Aware...
ABSTRACT We give an algorithm for finding a Fourier representation R of B terms for a given discrete...
Abstract. We present a range of new results for testing properties of Boolean functions that are def...
A. C. Gilbert S. Guha P. Indyk S. Muthukrishnan M. Strauss ABSTRACT We give an algorit...
This thesis focuses on developing efficient algorithmic tools for processing large datasets. In many...
Given an n-length input signal x, it is well known that its Discrete Fourier Transform (DFT), X, can...
Abstract. We present a range of new results for testing properties of Boolean functions that are def...
A function defined on the Boolean hypercube is k-Fourier-sparse if it has at most k nonzero Fourier ...