Influence as soft sparsity: Estimation of monotone functions on \0,1\d

Abstract

We study the problem of estimating a monotone function f:\0,1\d[0,1] from noisy observations at uniformly random vertices of the Boolean hypercube. As a measure of complexity for the target~f, we use the total L1-influence I(f)=Σ\i=1d([f(X) X\i=1]-[f(X) X\i=0]), a classical quantity in Boolean analysis that is nonnegative for monotone functions and controls the effective dimensionality of the estimation problem: through a spectral concentration result in the spirit of Friedgut's junta theorem, the Fourier spectrum of any f with I(f)≤slant K concentrates on low-degree subsets of the influential coordinates. We establish minimax bounds over the class \K=\f:\0,1\d[0,1],\;f monotone,\; I(f)≤slant K\: \[ c\,K2( n)3/2 \;≤slant\; ∈f\ f\;\f∈\K\; [\| f - f\|\22] \;≤slant\; C\,K n, \] where n is the sample size. The upper bound holds for all K≥slant 1 and is uniform in the ambient dimension~d (under the mild condition d≤slant n1-). It is achieved by a Fourier thresholding estimator that adapts to the unknown~K. The lower bound relies on a Varshamov--Gilbert packing on the middle layer of the hypercube combined with Fano's inequality.