Hemispherical Concentration Subset Recovery in Many-Access Gaussian Multiple-Access Channels

Abstract

We consider subset recovery in the many-access Gaussian multiple-access channel with a shared spherical codebook, where codewords are drawn independently and uniformly from the hypersphere of radius \( nP \), the number of active users scales linearly with the blocklength n as \( Ka(n)=β n \) for a constant \( β > 0 \), and the codebook size is \( Mn=nd \) with \( d>2 \). We identify a geometric property showing that, for \( 0<β<2 \), any transmitted \( Ka(n) \)-subset lies in a single hemisphere with high probability for sufficiently large n. We further show that reliable decoding is possible only for \( β < 1/4 \). The overlap between the reliable decoding range of \( β \) and the hemispherical concentration range motivates our approach of two-stage decoding procedure. In the pre-filtering stage, the decoder restricts attention to a sequence of spherical caps \( \ Hn \ \) that converges in Hausdorff distance to the hemisphere H, whose axis is the normalized observation \( u=Y/\|Y\| \). In the second stage, maximum-likelihood decoding is performed over the reduced candidate set. We show that the per-user error probability of the pre-filtering stage vanishes as \( n∞ \). Moreover, the per-user error probability of the maximum-likelihood stage over the reduced search space decays exponentially with asymptotic exponent \( P/4 \).