The Structure of Extremal Bad Science Matrices

Abstract

We study the 'bad science matrix problem': among all matrices A∈Rn× n whose rows have unit 2-norm, determine the maximum of β(A)=12nΣx∈\1\n\|Ax\|∞. Steinerberger [1] (arXiv:2402.03205) showed that the optimal asymptotic rate is (1+o(1))2 n, and that this rate is attained with high probability by matrices with i.i.d. 1 entries after normalization. More recent explicit constructions [2] (arXiv:2408.00933) achieve β(A)2(n)+1, which lies within a constant factor of the asymptotic optimum. In this paper we bridge the gap between the probabilistic and explicit approaches. We give a geometric description of extremizers as (nearly) isoperimetrically extremal partitions of the n-dimensional hypercube induced by the rows of A. We obtain precise rates for heuristic constructions by recasting the maximization of β(A) in the language of high-dimensional central-limit theorems as in Fang, Koike, Liu and Zhao [16] (arXiv:2305.17365). Using these connections, we present a family of explicit deterministic matrices An that exist for all n under the assumption of Hadamard's conjecture, and for infinitely many n unconditionally, such that for all n sufficiently large β(An)(1 - (2n)4(2n))2(2n).