Research Group Numerical Mathematics (Partial Differential Equations)

Prof. Dr. Roland Herzog

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Optimal Control of Stefan Problems with Constraints

General Information

• Funding: FWF-Project P19918-N14
• Period: 20.08.2007-19.08.2010
• Principal Investigators: Roland Herzog and Karl Kunisch
• Project Staff: Martin Bernauer

Keywords

• Optimal control
• Stefan problem
• State constraints
• Moving boundary problem
• Necessary optimality conditions

AMS Subject Classification

35R35, 49K20, 49M05, 80A22

Project Description

Free and moving boundary problems are ubiquitous in technical applications. They can serve as a model for free surfaces of liquids, or phase boundaries in phase transition phenomena etc. Free and moving boundary problems are characterized by the property that the domain of definition of the underlying partial differential equation is a priori unknown. By contrast, the domain is determined along with the solution of the equation.
This project is concerned with the optimal control of moving boundary problems involving time-dependent partial differential equations on two- and three-dimensional domains. We focus on problems of Stefan type which model phase transitions, for instance in solidification problems. In many industrial solidification processes, including casting and crystal growth, it is desirable to influence the evolution and shape of the free boundary, which affect the product quality or the duration of the production cycle. Mathematically, this can be expressed in terms of an objective functional, and the problem can be cast as an optimal control problem for a moving boundary problem. The objective function may depend on the location, area, or curvature of the free boundary, as well as on the state (temperature) and control (heat fluxes and sources) variables. For instance, the objective function may express the desired evolution of the moving boundary, its desired final location, or it may penalize large boundary curvature.
Often, inequality constraints are required in order to avoid excessive boundary heat fluxes, to guide the moving boundary in a band around its desired track, or to prevent the moving boundary from entering a specified area. In this project, we shall investigate numerical techniques for free boundary optimal control problems of Stefan type, with constraints on the location of the free boundary. In contrast to previous approaches, we shall utilize the structure of the optimality system, incorporate second-order information and employ level-set techniques to describe the evolution of the free surface. See also the project abstract at FWF .

Related Publications

• M. Bernauer, R. Herzog and K. Kunisch
  Optimal Control of the Two-Phase Stefan Problem in Level Set Formulation
  in: New Directions in Simulation, Control and Analysis for Interfaces and Free Boundaries
  Mathematisches Forschungsinstitut Oberwolfach, Report No. 07/2010, 2010

• Martin Bernauer and Roland Griesse: Implementation of an X-FEM Solver for the Classical Two-Phase Stefan Problem (submitted)
• Martin Bernauer and Roland Herzog: Optimal Control of the Classical Two-Phase Stefan Problem in Level Set Formulation (submitted)

Related Talks

• Martin Bernauer: Towards the Optimal Control of the One-Phase Stefan Problem, DMV Annual Meeting, September 15-19, 2008, Erlangen
• Martin Bernauer: Towards the Optimal Control of the One-Phase Stefan Problem, Chemnitz FEM Symposium, September 22-24, 2008, Chemnitz
• Martin Bernauer: Techniques for the Optimal Control of the One-Phase Stefan Problem, Research Seminar Numerics November 11, 2008, Chemnitz University of Technology
• Martin Bernauer: Motion Planning for the Two-Phase Stefan Problem in Level Set Formulation, Chemnitz Seminar on Optimal Control, March 7-14, 2009, Gerlosberg
• Martin Bernauer: Motion Planning for the Two-Phase Stefan Problem in Level Set Formulation, Optimization with interfaces and free boundaries, March 23-27, 2009, Regensburg
• Martin Bernauer: Optimal Control of the Two-Phase Stefan Problem: Numerical Approximation Techniques, Research Seminar Numerics June 2, 2009, Chemnitz University of Technology
• Martin Bernauer: Optimal Control of the Two-Phase Stefan Problem: Numerical Approximation Techniques, MAFELAP 2009 June 9-12, 2009, Brunel University, London
• Martin Bernauer: Optimal Control of the Two-Phase Stefan Problem Using Extended Finite Elements, Radon Seminar September 7, 2009, RICAM, Linz
• Martin Bernauer: XFEM for the Optimal Control of the Two-Phase Stefan Problem, ECCOMAS thematic event: XFEM 2009, September 28-30, 2009, Aachen
• Martin Bernauer: Optimal Control of the Two-Phase Stefan Problem in Level Set Formulation, Research Seminar Numerics November 10, 2009, Chemnitz University of Technology
• Martin Bernauer: Optimale Steuerung des klassischen Stefan Problems in zwei Phasen, Seminar on Applied Mathematics, January 11, 2010, University of Bayreuth
• Martin Bernauer: Optimal Control of the Two-Phase Stefan Problem in Level Set Formulation, Oberwolfach workshop on "New Directions in Simulation, Control and Analysis for Interfaces and Free Boundaries", January 31-February 6, 2010, Mathematisches Forschungsinstitut Oberwolfach
• Martin Bernauer: Optimal Control of the Classical Two-Phase Stefan Problem in Level Set Formulation, Chemnitz Seminar on Optimal Control, March 6-13, 2010, Haus im Ennstal

Upcoming Events

Roland Herzog
18 March 2010

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TU Chemnitz, Fakultät für Mathematik, 09107 Chemnitz

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