English

Improved Approximation of Linear Threshold Functions

Computational Complexity 2009-10-21 v1

Abstract

We prove two main results on how arbitrary linear threshold functions f(x)=\sign(wxθ)f(x) = \sign(w\cdot x - \theta) over the nn-dimensional Boolean hypercube can be approximated by simple threshold functions. Our first result shows that every nn-variable threshold function ff is \eps\eps-close to a threshold function depending only on \Inf(f)2\poly(1/\eps)\Inf(f)^2 \cdot \poly(1/\eps) many variables, where \Inf(f)\Inf(f) denotes the total influence or average sensitivity of f.f. This is an exponential sharpening of Friedgut's well-known theorem \cite{Friedgut:98}, which states that every Boolean function ff is \eps\eps-close to a function depending only on 2O(\Inf(f)/\eps)2^{O(\Inf(f)/\eps)} many variables, for the case of threshold functions. We complement this upper bound by showing that Ω(\Inf(f)2+1/ϵ2)\Omega(\Inf(f)^2 + 1/\epsilon^2) many variables are required for ϵ\epsilon-approximating threshold functions. Our second result is a proof that every nn-variable threshold function is \eps\eps-close to a threshold function with integer weights at most \poly(n)2O~(1/\eps2/3).\poly(n) \cdot 2^{\tilde{O}(1/\eps^{2/3})}. This is a significant improvement, in the dependence on the error parameter \eps\eps, on an earlier result of \cite{Servedio:07cc} which gave a \poly(n)2O~(1/\eps2)\poly(n) \cdot 2^{\tilde{O}(1/\eps^{2})} bound. Our improvement is obtained via a new proof technique that uses strong anti-concentration bounds from probability theory. The new technique also gives a simple and modular proof of the original \cite{Servedio:07cc} result, and extends to give low-weight approximators for threshold functions under a range of probability distributions beyond just the uniform distribution.

Keywords

Cite

@article{arxiv.0910.3719,
  title  = {Improved Approximation of Linear Threshold Functions},
  author = {Ilias Diakonikolas and Rocco A. Servedio},
  journal= {arXiv preprint arXiv:0910.3719},
  year   = {2009}
}

Comments

full version of CCC'09 paper

R2 v1 2026-06-21T14:00:34.502Z