Zusammenfassung
Optimization problems constrained by time-dependent Partial
Differential Equations (PDEs) are challenging from a computational
point of view: even in the simplest case, one needs to solve a system
of PDEs coupled globally in time and space for the unknown solutions
(the state, the costate and the control of the system). Typical and
practically relevant examples are the control of nonlinear heat
equations as they appear in laser hardening or the thermic control of
flow problems (Boussinesq equations). Specifically for PDEs with a
long time horizon, conventional time-stepping methods require an
enormous amount of computer memory allocations for the respective
other variables. In contrast, adaptive-in-time-and-space methods aim
at distributing the available degrees of freedom in an a-posteriori
fashion to capture singularities and are, therefore, most
promising. Recently, well-posed weak variational formulations have
been introduced for time-dependent PDEs such as the heat equation,
linear transport and the wave equation. Those formulations also allow
for a sharp relation between the approximation error and the residual,
which is particularly relevant for model reduction. Moreover, for
those tensor-basis formulations, advanced algebraic solvers
designed to take into account these multiarray
(tensorial) formulations appear to be particularly competitive with
respect to time-marching schemes, especially in higher dimensions. We
plan to discuss whether these techniques can be extended to nonlinear
PDEs like Hamilton-Jacobi-Bellman equations, or stochastic PDEs and
variational inequalities. Another topic will be adaptive schemes
which, when properly designed, inherit the stability of the continuous
formulation.
The central goals of the workshop are the analysis, fast solvers and model
reduction for PDE-constrained control and optimization problems based on
weak formulations of the underlying PDE(s).