Hessian barrier algorithms for linearly constrained optimization problems

Immanuel M. Bomze, Panayotis Mertikopoulos, Werner Schachinger, Mathias Staudigl

Publications: Contribution to journalArticlePeer Reviewed

Abstract

In this paper, we propose an interior-point method for linearly constrained optimization problems (possibly nonconvex). The method - which we call the Hessian barrier algorithm (HBA) - combines a forward Euler discretization of Hessian Riemannian gradient flows with an Armijo backtracking step-size policy. In this way, HBA can be seen as an alternative to mirror descent (MD), and contains as special cases the affine scaling algorithm, regularized Newton processes, and several other iterative solution methods. Our main result is that, modulo a non-degeneracy condition, the algorithm converges to the problem's set of critical points; hence, in the convex case, the algorithm converges globally to the problem's minimum set. In the case of linearly constrained quadratic programs (not necessarily convex), we also show that the method's convergence rate is $\mathcal{O}(1/k^\rho)$ for some $\rho\in(0,1]$ that depends only on the choice of kernel function (i.e., not on the problem's primitives). These theoretical results are validated by numerical experiments in standard non-convex test functions and large-scale traffic assignment problems.
Original languageEnglish
Pages (from-to)2100–2127
Number of pages28
JournalSIAM Journal on Optimization
Volume29
Issue number3
Early online date27 Aug 2019
DOIs
Publication statusPublished - 2019

Austrian Fields of Science 2012

  • 101015 Operations research

Keywords

  • math.OC
  • cs.LG
  • Primary: 90C51, 90C30, secondary: 90C25, 90C26
  • interior-point methods
  • nonconvex optimization
  • DESCENT
  • GRADIENT
  • Hessian-Riemannian gradient descent
  • traffic assignment
  • CONVEX
  • DYNAMICAL-SYSTEMS
  • CONVERGENCE
  • FLOWS
  • mirror descent
  • Nonconvex optimization
  • Interior-point methods
  • Mirror descent
  • Traffic assignment

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