The Log-Volume of Optimal Codes for Memoryless Channels, Asymptotically Within A Few Nats

Abstract

Shannon's analysis of the fundamental capacity limits for memoryless communication channels has been refined over time. In this paper, the maximum volume M*(n,ε) of length-n codes subject to an average decoding error probability ε is shown to satisfy the following tight asymptotic lower and upper bounds as n ∞: \[ Aε + o(1) M*(n,ε) - [nC - nVε \,Q-1(ε) + 12 n] Aε + o(1) \] where C is the Shannon capacity, Vε the ε-channel dispersion, or second-order coding rate, Q the tail probability of the normal distribution, and the constants Aε and Aε are explicitly identified. This expression holds under mild regularity assumptions on the channel, including nonsingularity. The gap Aε - Aε is one nat for weakly symmetric channels in the Cover-Thomas sense, and typically a few nats for other symmetric channels, for the binary symmetric channel, and for the Z channel. The derivation is based on strong large-deviations analysis and refined central limit asymptotics. A random coding scheme that achieves the lower bound is presented. The codewords are drawn from a capacity-achieving input distribution modified by an O(1/n) correction term.