A Complex Analogue of Spencer's Six Standard Deviations Theorem and the Complex Banach-Mazur Distance

Abstract

We investigate a complex analogue of Spencer's Six Standard Deviations Theorem. Specifically, we propose the following conjecture: for any dimension n ≥ 2, given vectors a1, …, an ∈ Cn satisfying \|ai\|∞ ≤ 1 for each i=1, …, n, there exists a vector x ∈ Cn with all coordinates of modulus one such that | x, ai | ≤ n for every i=1, …, n. The bound of n is sharp, as demonstrated by the row vectors of any complex n × n Hadamard matrix. Furthermore, if the conjecture holds in dimension n, it implies that the Banach--Mazur distance between the complex 1n and ∞n spaces is equal to n. We prove the conjecture for n =2, 3, thereby establishing also that dBM(1n, ∞n) = n for these dimensions. Additionally, we propose a conjecture about the Banach--Mazur distances between complex pn spaces and we verify it for n=2. This leads to a complete determination of all possible Banach--Mazur distances between complex p2 spaces.