On the tightness of Tiet\"av\"ainen's bound for distributions with limited independence

Abstract

In 1990, Tiet\"av\"ainen showed that if the only information we know about a linear code is its dual distance d, then its covering radius R is at most n2-(12-o(1))dn. While Tiet\"av\"ainen's bound was later improved for large values of d, it is still the best known upper bound for small values including the d = o(n) regime. Tiet\"av\"ainen's bound holds also for (d-1)-wise independent probability distributions on \0,1\n, of which linear codes with dual distance d are special cases. We show that Tiet\"av\"ainen's bound on R-n2 is asymptotically tight up to a factor of 2 for k-wise independent distributions if k≤n1/32n. Namely, we show that there exists a k-wise independent probability distribution μ on \0,1\n whose covering radius is at least n2-kn. Our key technical contribution is the following lemma on low degree polynomials, which implies the existence of μ by linear programming duality. We show that, for sufficiently large k≤n1/32n and for each polynomial f(v)∈ R[v] of degree at most k, the expected value of f with respect to the binomial distribution cannot be positive if f(w)≤ 0 for each integer w such that |w-n/2|≤kn. The proof uses tools from approximation theory.