From Nonsmooth Minima to Smooth Branches via Heat Kernel Regularization
Abstract
Many optimization problems in science and engineering involve objective functions that are nonsmooth at their minimizers. A common strategy is to trace a branch of minimizers of a regularized objective as the smoothing scale tends to zero; however, for nonsmooth functions, it is generally unclear whether such a branch can be continued and whether the associated continuation equation remains locally solvable. We study heat-kernel regularization and the resulting continuation equation along a local minimizing branch connected to a minimizer of the original objective. Under a global growth condition and a local leading-order description of the form with , we first show that the regularized objective admits global minimizers and that any such minimizing branch localizes at the natural heat scale . We then prove that the asymptotic behavior of the regularized Hessian is determined by the local profile of the original objective: it remains uniformly positive definite in the quadratic case , while in the subquadratic regime its smallest eigenvalue grows at the controlled rate . Consequently, the regularized Hessian remains asymptotically nondegenerate for all sufficiently small , and the continuation equation remains locally solvable, even when the original objective does not admit a classical Hessian at the minimizer. Our results provide a rigorous second-order framework for continuation-based analysis in nonsmooth optimization by showing how heat regularization restores nondegeneracy near singular minimizers.
Keywords
Cite
@article{arxiv.2604.05372,
title = {From Nonsmooth Minima to Smooth Branches via Heat Kernel Regularization},
author = {Hyeontae Jo},
journal= {arXiv preprint arXiv:2604.05372},
year = {2026}
}