Ising Model Selection Using $\ell_{1}$-Regularized Linear Regression: A Statistical Mechanics Analysis
Abstract
We theoretically analyze the typical learning performance of -regularized linear regression (-LinR) for Ising model selection using the replica method from statistical mechanics. For typical random regular graphs in the paramagnetic phase, an accurate estimate of the typical sample complexity of -LinR is obtained. Remarkably, despite the model misspecification, -LinR is model selection consistent with the same order of sample complexity as -regularized logistic regression (-LogR), i.e., , where is the number of variables of the Ising model. Moreover, we provide an efficient method to accurately predict the non-asymptotic behavior of -LinR for moderate , such as precision and recall. Simulations show a fairly good agreement between theoretical predictions and experimental results, even for graphs with many loops, which supports our findings. Although this paper mainly focuses on -LinR, our method is readily applicable for precisely characterizing the typical learning performances of a wide class of -regularized -estimators including -LogR and interaction screening.
Cite
@article{arxiv.2102.03988,
title = {Ising Model Selection Using $\ell_{1}$-Regularized Linear Regression: A Statistical Mechanics Analysis},
author = {Xiangming Meng and Tomoyuki Obuchi and Yoshiyuki Kabashima},
journal= {arXiv preprint arXiv:2102.03988},
year = {2022}
}
Comments
Accepted to NeurIPS 2021. Camera-ready version with supplementary materials