Covariance-Domain Near-Field Channel Estimation under Hybrid Compression: USW/Fresnel Model, Curvature Learning, and KL Covariance Fitting
Abstract
Near-field propagation in extremely large aperture arrays requires joint angle-range estimation. In hybrid architectures, only NRF M compressed snapshots are available per slot, making the NRF× NRF compressed sample covariance the natural sufficient statistic. We propose the Curvature-Learning KL (CL-KL) estimator, which grids only the angle dimension and learns the per-angle inverse range directly from the compressed covariance via KL divergence minimisation. CL-KL uses a Qθ-element dictionary instead of the Qθ Qr atoms of 2-D polar gridding, eliminating the range-dimension dictionary coherence that plagues polar codebooks in the strong near-field regime, and operates entirely on the compressed covariance for full compatibility with hybrid front-ends. At NMC=400 (fc=28~GHz, M=64, NRF=8, N=64, d=3, r∈[0.05,1.0]\,rRD), CL-KL achieves the lowest channel NMSE among all six evaluated methods -- including four full-array baselines using 64× more data -- at SNR∈\-5,0,+5,+10\~dB. Running in approximately 70~ms per trial (vs.\ 5~ms for the compressed-domain peer P-SOMP), CL-KL's dominant cost is the NRF×NRF inversion rather than M: measured runtime stays near 70~ms across M∈\32,64,128,256\, making it aperture-scalable for XL-MIMO deployments. CL-KL is further validated against a derived compressed-domain Cram\'er-Rao bound and confirmed robust to non-Gaussian (QPSK) source distributions, with a maximum NMSE gap below 0.6~dB.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.