Support Size of -Capacity-Achieving Inputs for the Amplitude-Constrained AWGN Channel

Abstract

We study the amplitude-constrained additive white Gaussian noise (AWGN) channel from the perspective of near-optimal input distributions. While it is known that the capacity-achieving input is discrete with finitely many mass points, the precise scaling of its support size as a function of the amplitude constraint remains an open problem. In this work, we instead consider the minimal support size required to achieve capacity up to an -gap. We introduce the quantity K(A), defined as the smallest support size among discrete inputs supported on [-A,A] that achieves mutual information within of capacity. We show that this relaxed formulation is significantly more tractable and admits sharp characterizations across different regimes of . In particular, when decays polynomially with A, i.e., = A-β for β ≥ 1, we establish that K(A) = (A A). For exponentially small gaps, we obtain bounds of order between A A and A3/2. Our approach combines approximation-theoretic bounds for Gaussian mixtures with information-theoretic control of entropy via 2-divergence, together with a wrapping argument that relates the problem to approximating the uniform distribution on the circle. Beyond the technical results, our framework provides a conceptual explanation for the variety of scaling laws observed in prior numerical studies, showing that these correspond to different regimes of -optimality rather than intrinsic properties of the exact optimizer.