TY - JOUR
T1 - POD–Galerkin Model Order Reduction for Parametrized Time Dependent Linear Quadratic Optimal Control Problems in Saddle Point Formulation
AU - Strazzullo, Maria
AU - Ballarin, Francesco
AU - Rozza, Gianluigi
PY - 2020
Y1 - 2020
N2 - In this work we deal with parametrized time dependent optimal control problems governed by partial differential equations. We aim at extending the standard saddle point framework of steady constraints to time dependent cases. We provide an analysis of the well-posedness of this formulation both for parametrized scalar parabolic constraint and Stokes governing equations and we propose reduced order methods as an effective strategy to solve them. Indeed, on one hand, parametrized time dependent optimal control is a very powerful mathematical model which is able to describe several physical phenomena, on the other, it requires a huge computational effort. Reduced order methods are a suitable approach to have rapid and accurate simulations. We rely on POD–Galerkin reduction over the physical and geometrical parameters of the optimality system in a space-time formulation. Our theoretical results and our methodology are tested on two examples: a boundary time dependent optimal control for a Graetz flow and a distributed optimal control governed by time dependent Stokes equations. With these two test cases the convenience of the reduced order modelling is further extended to the field of time dependent optimal control.
AB - In this work we deal with parametrized time dependent optimal control problems governed by partial differential equations. We aim at extending the standard saddle point framework of steady constraints to time dependent cases. We provide an analysis of the well-posedness of this formulation both for parametrized scalar parabolic constraint and Stokes governing equations and we propose reduced order methods as an effective strategy to solve them. Indeed, on one hand, parametrized time dependent optimal control is a very powerful mathematical model which is able to describe several physical phenomena, on the other, it requires a huge computational effort. Reduced order methods are a suitable approach to have rapid and accurate simulations. We rely on POD–Galerkin reduction over the physical and geometrical parameters of the optimality system in a space-time formulation. Our theoretical results and our methodology are tested on two examples: a boundary time dependent optimal control for a Graetz flow and a distributed optimal control governed by time dependent Stokes equations. With these two test cases the convenience of the reduced order modelling is further extended to the field of time dependent optimal control.
KW - Proper orthogonal decomposition
KW - Reduced order methods
KW - Saddle point formulation
KW - Time dependent PDEs state equations
KW - Time dependent parametrized optimal control problems
KW - Proper orthogonal decomposition
KW - Reduced order methods
KW - Saddle point formulation
KW - Time dependent PDEs state equations
KW - Time dependent parametrized optimal control problems
UR - http://hdl.handle.net/10807/174178
U2 - 10.1007/s10915-020-01232-x
DO - 10.1007/s10915-020-01232-x
M3 - Article
SN - 0885-7474
VL - 83
SP - 1
EP - 35
JO - Journal of Scientific Computing
JF - Journal of Scientific Computing
ER -