TY - JOUR

T1 - Space-Time Mixed System Formulation of Phase-Field Fracture Optimal Control Problems

AU - Khimin, Denis

AU - Steinbach, Marc Christian

AU - Wick, Thomas

N1 - Funding Information: Submitted to the editors Jan 25, 2023. The first and third author are partially funded by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) Priority Program 1962 (DFG SPP 1962) within the subproject Optimizing Fracture Propagation using a Phase-Field Approach with the project number 314067056. The second author is funded by the DFG – SFB1463 – 434502799.

PY - 2023/12

Y1 - 2023/12

N2 - In this work, space-time formulations and Galerkin discretizations for phase-field fracture optimal control problems are considered. The fracture irreversibility constraint is formulated on the time-continuous level and is regularized by means of penalization. The optimization scheme is formulated in terms of the reduced approach and then solved with a Newton method. To this end, the state, adjoint, tangent, and adjoint Hessian equations are derived. The key focus is on the design of appropriate function spaces and the rigorous justification of all Fréchet derivatives that require fourth-order regularizations. Therein, a second-order time derivative on the phase-field variable appears, which is reformulated as a mixed first-order-in-time system. These derivations are carefully established for all four equations. Finally, the corresponding time-stepping schemes are derived by employing a dG(r) discretization in time.

AB - In this work, space-time formulations and Galerkin discretizations for phase-field fracture optimal control problems are considered. The fracture irreversibility constraint is formulated on the time-continuous level and is regularized by means of penalization. The optimization scheme is formulated in terms of the reduced approach and then solved with a Newton method. To this end, the state, adjoint, tangent, and adjoint Hessian equations are derived. The key focus is on the design of appropriate function spaces and the rigorous justification of all Fréchet derivatives that require fourth-order regularizations. Therein, a second-order time derivative on the phase-field variable appears, which is reformulated as a mixed first-order-in-time system. These derivations are carefully established for all four equations. Finally, the corresponding time-stepping schemes are derived by employing a dG(r) discretization in time.

KW - Mixed-in-time system

KW - Optimal control

KW - Penalization

KW - Phase-field fracture propagation

KW - Reduced optimization approach

UR - http://www.scopus.com/inward/record.url?scp=85165986595&partnerID=8YFLogxK

U2 - 10.1007/s10957-023-02272-7

DO - 10.1007/s10957-023-02272-7

M3 - Article

AN - SCOPUS:85165986595

VL - 199

SP - 1222

EP - 1248

JO - Journal of Optimization Theory and Applications

JF - Journal of Optimization Theory and Applications

SN - 0022-3239

IS - 3

ER -