A Statistical-Physics Refinement of Soft Covering

Abstract

We study the channel output distribution induced by a rate-R random code via statistical physics. The partition function is Zn(β|C) = Σyn[PYn|C(yn)]β, where C is the code and β > 0 is inverse temperature. Our focus is on the free energy which is the normalized logarithm of this quantity, which encodes the full R\'enyi spectrum of the output distribution. The single-letter formula derived for the annealed free energy decomposes into two branches which reflect a ``competition'' between two populations of codewords. One is the bulk branch, b(β,R), which is driven by typical codewords and the other one is the sparse branch s(β,R), which is driven by a-typical codewords, where the qualifiers `typical' and `atypical' are in a sense to become apparent later. We analyze the phase structure of each branch separately and characterize their competition. Both branches are derived for all β > 0. The phase boundary R(β), where the two branches are equal, is analyzed for β ≥ 1, where it has an explicit closed-form expression. The phase diagram in the first quadrant of the (β, R) plane has four regions separated by three boundaries: R = I b(β) (bulk branch transition), R = R(β) (bulk--sparse competition boundary), and R = I s(β) (sparse branch transition), all meeting at the point (β, R) = (1, I(X;Y)), where I(X;Y) is the mutual information induced by the input type and the channel. Applications to guesswork, channel resolvability, and hypothesis testing are discussed, and all results are illustrated with a numerical example of a Z-channel.