Fitting an ellipsoid to random points: predictions using the replica method
Abstract
We consider the problem of fitting a centered ellipsoid to standard Gaussian random vectors in , as with . It has been conjectured that this problem is, with high probability, satisfiable (SAT; that is, there exists an ellipsoid passing through all points) for , and unsatisfiable (UNSAT) for . In this work we give a precise analytical argument, based on the non-rigorous replica method of statistical physics, that indeed predicts a SAT/UNSAT transition at , as well as the shape of a typical fitting ellipsoid in the SAT phase (i.e., the lengths of its principal axes). Besides the replica method, our main tool is the dilute limit of extensive-rank "HCIZ integrals" of random matrix theory. We further study different explicit algorithmic constructions of the matrix characterizing the ellipsoid. In particular, we show that a procedure based on minimizing its nuclear norm yields a solution in the whole SAT phase. Finally, we characterize the SAT/UNSAT transition for ellipsoid fitting of a large class of rotationally-invariant random vectors. Our work suggests mathematically rigorous ways to analyze fitting ellipsoids to random vectors, which is the topic of a companion work.
Cite
@article{arxiv.2310.01169,
title = {Fitting an ellipsoid to random points: predictions using the replica method},
author = {Antoine Maillard and Dmitriy Kunisky},
journal= {arXiv preprint arXiv:2310.01169},
year = {2024}
}
Comments
41 pages. Update to match the published version