Finite-Step Bounds for Iterated Correlation Matrices
Abstract
We establish finite-step probabilistic upper bounds on the contraction ratios for iterated Pearson correlation dynamics. Let be the sequence generated by the Pearson update. Define , for , and . Although along convergent trajectories, the ratios may exceed unity in finitely many steps. This behavior is invisible to local linearization. Our main contribution is a probabilistic bounding framework that captures these finite-step expansions. We initialize with i.i.d. entries and let be the induced measure. For , we construct state-dependent bounds satisfying . The functions are empirical conditional -quantiles of given under logarithmic binning. Larger families and are obtained via multiplicative adjustments, yielding pointwise larger bounds that preserve the -dependence. Validation on held-out trajectories confirms the bounds hold with empirical coverage matching nominal levels for all . The baseline -quantile bound yields two concrete results: uniformly in , and for 21 of 22 dimensions. The exception attains , revealing a rare extreme upper tail discontinuity not captured by asymptotic analysis. These are the first finite-step probabilistic bounds for Pearson correlation dynamics. The framework is fully reproducible with provided code and data.
Keywords
Cite
@article{arxiv.2604.14071,
title = {Finite-Step Bounds for Iterated Correlation Matrices},
author = {Ishrak AlhajjHassan},
journal= {arXiv preprint arXiv:2604.14071},
year = {2026}
}