English

Improved Extractors for Affine Lines

Computational Complexity 2013-12-05 v2

Abstract

Let FF be the field of qq elements. We investigate the following Ramsey coloring problem for vector spaces: Given a vector space \Fn\F^n, give a coloring of the points of FnF^n with two colors such that no affine line (i.e., affine subspace of dimension 11) is monochromatic. Our main result is as follows: For any q25nq\geq 25\cdot n and n>4n>4, we give an explicit coloring D:Fn\ar{0,1}D:F^n\ar \set{0,1} such that for every affine line lFnl\subseteq F^n, D(l)={0,1}D(l)=\set{0,1}. Previously this was known only for qcn2q\geq c\cdot n^2 for some constant cc \cite{GR05}. We note that this beats the random coloring for which the expected number of monochromatic lines will be 0 only when qcnlognq\geq c\cdot n\log n for some constant cc. Furthermore, our coloring will be `almost balanced' on every affine line. Let us state this formally in the lanuage of \emph{extractors}. We say that a function D:Fn{0,1}D:F^n\mapsto \set{0,1} is a \afsext{1}{\eps} if for every affine line l\Fnl\subseteq \F^n, D(X)D(X) is \eps\eps-close to uniform when XX is uniformly distributed over ll. We construct a \afsext{1}{\eps} with \eps=Ω(n/q)\eps = \Omega(\sqrt{n/q}) whenever qcnq\geq c\cdot n for some constant cc. The previous result of \cite{GR05} gave a \afsext{1}{\eps} only for q=Ω(n2)q=\Omega(n^2).

Cite

@article{arxiv.1311.5622,
  title  = {Improved Extractors for Affine Lines},
  author = {Ariel Gabizon},
  journal= {arXiv preprint arXiv:1311.5622},
  year   = {2013}
}

Comments

The paper has been withdrawn as it is being merged into a joint paper with additional authors

R2 v1 2026-06-22T02:12:37.042Z