TY - JOUR
T1 - POD-Galerkin model order reduction for parametrized nonlinear time-dependent optimal flow control: An application to shallow water equations
AU - Strazzullo, Maria
AU - Ballarin, Francesco
AU - Rozza, Gianluigi
PY - 2022
Y1 - 2022
N2 - In the present paper we propose reduced order methods as a reliable strategy to efficiently solve parametrized optimal control problems governed by shallow waters equations in a solution tracking setting. The physical parametrized model we deal with is nonlinear and time dependent: this leads to very time consuming simulations which can be unbearable, e.g., in a marine environmental monitoring plan application. Our aim is to show how reduced order modelling could help in studying different configurations and phenomena in a fast way. After building the optimality system, we rely on a POD-Galerkin reduction in order to solve the optimal control problem in a low dimensional reduced space. The presented theoretical framework is actually suited to general nonlinear time dependent optimal control problems. The proposed methodology is finally tested with a numerical experiment: the reduced optimal control problem governed by shallow waters equations reproduces the desired velocity and height profiles faster than the standard model, still remaining accurate.
AB - In the present paper we propose reduced order methods as a reliable strategy to efficiently solve parametrized optimal control problems governed by shallow waters equations in a solution tracking setting. The physical parametrized model we deal with is nonlinear and time dependent: this leads to very time consuming simulations which can be unbearable, e.g., in a marine environmental monitoring plan application. Our aim is to show how reduced order modelling could help in studying different configurations and phenomena in a fast way. After building the optimality system, we rely on a POD-Galerkin reduction in order to solve the optimal control problem in a low dimensional reduced space. The presented theoretical framework is actually suited to general nonlinear time dependent optimal control problems. The proposed methodology is finally tested with a numerical experiment: the reduced optimal control problem governed by shallow waters equations reproduces the desired velocity and height profiles faster than the standard model, still remaining accurate.
KW - nonlinear time dependent parametrized optimal control problem
KW - proper orthogonal decomposition
KW - reduced order method
KW - shallow water state equations
KW - nonlinear time dependent parametrized optimal control problem
KW - proper orthogonal decomposition
KW - reduced order method
KW - shallow water state equations
UR - http://hdl.handle.net/10807/202828
U2 - 10.1515/jnma-2020-0098
DO - 10.1515/jnma-2020-0098
M3 - Article
SN - 1570-2820
VL - 30
SP - 63
EP - 84
JO - Journal of Numerical Mathematics
JF - Journal of Numerical Mathematics
ER -