Nearly optimal solutions for the Chow Parameters Problem and low-weight approximation of halfspaces

Abstract

The Chow parameters of a Boolean function f: \-1,1\n \-1,1\ are its n+1 degree-0 and degree-1 Fourier coefficients. It has been known since 1961 (Chow, Tannenbaum) that the (exact values of the) Chow parameters of any linear threshold function f uniquely specify f within the space of all Boolean functions, but until recently (O'Donnell and Servedio) nothing was known about efficient algorithms for reconstructing f (exactly or approximately) from exact or approximate values of its Chow parameters. We refer to this reconstruction problem as the Chow Parameters Problem. Our main result is a new algorithm for the Chow Parameters Problem which, given (sufficiently accurate approximations to) the Chow parameters of any linear threshold function f, runs in time O(n2)· (1/)O(2(1/)) and with high probability outputs a representation of an LTF f' that is -close to f. The only previous algorithm (O'Donnell and Servedio) had running time (n) · 22O(1/2). As a byproduct of our approach, we show that for any linear threshold function f over \-1,1\n, there is a linear threshold function f' which is -close to f and has all weights that are integers at most n · (1/)O(2(1/)). This significantly improves the best previous result of Diakonikolas and Servedio which gave a (n) · 2O(1/2/3) weight bound, and is close to the known lower bound of \n, (1/)( (1/))\ (Goldberg, Servedio). Our techniques also yield improved algorithms for related problems in learning theory.