An Improved Lower Bound on Support Size of Capacity-Achieving Inputs for the Binomial Channel: Extended version

Abstract

We study the binomial channel and the structure of its capacity-achieving input and output distributions. It is known that the capacity-achieving input distribution is discrete and supported on finitely many points. The best previously known bounds show that the support size of the capacity-achieving distribution is lower-bounded by a term of order n and upper-bounded by a term of order n/2, where n is the number of trials. In this work, we derive a new lower bound on the support size of order n n, up to explicit constants. The proof consists of three main steps. First, we derive new upper and lower bounds on the capacity with a gap that vanishes as n∞, which yields C(n)=12nπ2e+o(1). Second, we show that the Beta-binomial output distribution induced by the reference input Xr(1/2,1/2) is asymptotically optimal: it approaches the capacity-achieving output distribution in relative entropy and, after a comparison step, in 2 divergence. Third, we prove a quantitative 2 approximation lower bound showing that this Beta-binomial output cannot be approximated too well by the output induced by a K-point input. Combining these ingredients forces the capacity-achieving input distribution to have at least order n n mass points.