English

Asymptotic Theory for Graphical SLOPE: Precision Estimation and Pattern Convergence

Statistics Theory 2026-04-15 v1 Applications Methodology Machine Learning Statistics Theory

Abstract

This paper studies Graphical SLOPE for precision matrix estimation, with emphasis on its ability to recover both sparsity and clusters of edges with equal or similar strength. In a fixed-dimensional regime, we establish that the root-nn scaled estimation error converges to the unique minimizer of a strictly convex optimization problem defined through the directional derivative of the SLOPE penalty. We also establish convergence of the induced SLOPE pattern, thereby obtaining an asymptotic characterization of the clustering structure selected by the estimator. A comparison with GLASSO shows that the grouping property of SLOPE can substantially improve estimation accuracy when the precision matrix exhibits structured edge patterns. To assess the effect of departures from Gaussianity, we then analyze Gaussian-loss precision matrix estimation under elliptical distributions. In this setting, we derive the limiting distribution and quantify the inflation in variability induced by heavy tails relative to the Gaussian benchmark. We also study TSLOPE, based on the multivariate tt-loss, and derive its limiting distribution. The results show that TSLOPE offers clear advantages over GSLOPE under heavy-tailed data-generating mechanisms. Simulation evidence suggests that these qualitative conclusions persist in high-dimensional settings, and an empirical application shows that SLOPE-based estimators, especially TSLOPE, can uncover economically meaningful clustered dependence structures.

Keywords

Cite

@article{arxiv.2604.12771,
  title  = {Asymptotic Theory for Graphical SLOPE: Precision Estimation and Pattern Convergence},
  author = {Ivan Hejný and Giovanni Bonaccolto and Philipp Kremer and Sandra Paterlini and Małgorzata Bogdan and Jonas Wallin},
  journal= {arXiv preprint arXiv:2604.12771},
  year   = {2026}
}

Comments

38 pages, 11 figures

R2 v1 2026-07-01T12:08:55.952Z