Algebraic Diversity: Group-Theoretic Spectral Estimation from Single Observations
Abstract
We establish that temporal averaging over multiple observations is the degenerate case of algebraic group action with the trivial group . A General Replacement Theorem proves that a group-averaged estimator from one snapshot achieves equivalent subspace decomposition to multi-snapshot covariance estimation. The Trivial Group Embedding Theorem proves that the sample covariance is the accumulation of trivial-group estimates, with variance governed by a continuum as . The processing gain dB equals the classical beamforming gain, establishing that this gain is a property of group order, not sensor count. The DFT, DCT, and KLT are unified as group-matched special cases. We conjecture a General Algebraic Averaging Theorem extending these results to arbitrary statistics, with variance governed by the effective group order . Monte Carlo experiments on the first four sample moments across five group types confirm the conjecture to four-digit precision. The framework exploits the of information (representation-theoretic symmetry of the data object) rather than the content, complementing Shannon's theory. Five applications are demonstrated: single-snapshot MUSIC, massive MIMO, single-pulse waveform classification, graph signal processing, and analysis of transformer LLMs. Techniques for blind group matching are described.
Cite
@article{arxiv.2604.03634,
title = {Algebraic Diversity: Group-Theoretic Spectral Estimation from Single Observations},
author = {Mitchell A. Thornton},
journal= {arXiv preprint arXiv:2604.03634},
year = {2026}
}
Comments
41 pages, 14 figures. v3: Retracted six quantitative findings in Section 11, transformer application, due to implementation error in spectral concentration metric. Corrected results deferred to separate publication. Remark added after Conjecture 23 on orbit-structure bias in psi criterion. All other sections unaffected v4: new result on blind group matching