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Autores principales: Ruppenthal, Falko, Ridzal, Denis, Kuzmin, Dmitri, Bochev, Pavel
Formato: Preprint
Publicado: 2024
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Acceso en línea:https://arxiv.org/abs/2412.18685
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author Ruppenthal, Falko
Ridzal, Denis
Kuzmin, Dmitri
Bochev, Pavel
author_facet Ruppenthal, Falko
Ridzal, Denis
Kuzmin, Dmitri
Bochev, Pavel
contents Optimization-based (OB) alternatives to traditional flux limiters couch preservation of properties such as local bounds and maximum principles into optimization problems, which impose these properties through inequality constraints. In this paper, we propose a new potential-target OB approach that enforces these properties using an optimal control formulation, in which the control is the source term expressed through flux potentials. The resulting OB formulation combines superb accuracy with excellent local conservation properties, but complicates the development of scalable iterative solvers, which is greatly influenced by the choice of semi-norms for the objective function. We use this fact to design scalable iterative solvers based on matrix-free trust-region Newton methods with projections onto convex sets. These solvers leverage inexpensive multigrid V-cycles while satisfying all constraints to machine precision. Numerical experiments reveal that the convergence behavior of the solvers can be greatly improved by a simple scaling of the inequality constraints. We demonstrate excellent performance in applications to linear test problems, such as $L^2$ projection and solid body rotation, and to the Cahn-Hilliard equation.
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spellingShingle Scalable optimal control for inequality-constrained discretizations of scalar conservation laws
Ruppenthal, Falko
Ridzal, Denis
Kuzmin, Dmitri
Bochev, Pavel
Optimization and Control
Optimization-based (OB) alternatives to traditional flux limiters couch preservation of properties such as local bounds and maximum principles into optimization problems, which impose these properties through inequality constraints. In this paper, we propose a new potential-target OB approach that enforces these properties using an optimal control formulation, in which the control is the source term expressed through flux potentials. The resulting OB formulation combines superb accuracy with excellent local conservation properties, but complicates the development of scalable iterative solvers, which is greatly influenced by the choice of semi-norms for the objective function. We use this fact to design scalable iterative solvers based on matrix-free trust-region Newton methods with projections onto convex sets. These solvers leverage inexpensive multigrid V-cycles while satisfying all constraints to machine precision. Numerical experiments reveal that the convergence behavior of the solvers can be greatly improved by a simple scaling of the inequality constraints. We demonstrate excellent performance in applications to linear test problems, such as $L^2$ projection and solid body rotation, and to the Cahn-Hilliard equation.
title Scalable optimal control for inequality-constrained discretizations of scalar conservation laws
topic Optimization and Control
url https://arxiv.org/abs/2412.18685