Current research in the control of PDEs is focused on highly nonlinear coupled systems of partial differential equations that arise from diverse applications in engineering and science. Dealing with associated control problems calls for a careful analysis of such systems, efficient numerical methods for differential equations and powerful techniques of numerical optimization. The program of the conference contained a blend of associated talks. Systems modelling quantum effects, dynamic fluid-structure interaction, the coupling of heat transport or fluid flow with electromagnetic fields and compressible flows were subject of the talks. Main aspects of control theory were stateconstrained optimal control, mesh-adaptivity and a posteriori error estimation, feedback control, free material and shape optimization, controllability and observability. The conference tightened the links between applications, numerics, and analysis with some emphasis on the analytic aspects. Mathematics Subject Classification (2000): 49J20,35Qxx,65K05. Introduction by the Organisers The international conference Optimal Control of Coupled Systems of PDE, was held March 2ndâMarch 8th, 2008, organized by K. Kunisch (Karl-Franzens-University Graz), G. Leugering (University of Erlangen-Nurnberg), J. Sprekels (Weierstrass Institute of Applied Analysis and Stochastics Berlin) and Fredi Troltzsch (Technische Universitat Berlin). 44 participants attended this meeting and followed 33 talks on optimal control and related topics. Mathematically, the control of partial differential equations (PDEs) is concerned with the following type of problems: The solution of a PDE (the state of the system) should be influenced in a desired way by the choice of certain control functions or control parameters (the controls), which may occur in different terms 588 Oberwolfach Report 13/2008 of the differential equation. If the controls are to minimize a certain functional related to the state, then an optimal control problem is posed. If the domain underlying the PDE is subject of the control, then a shape optimization problem is given. For evolution equations, it can be required to move the solution from a given initial state exactly to a desired final state. This is the question of exact controllability. Optimization and control of partial differential equations continues to be a very active field of research. Scientists working in different fields came together to report on their contributions to the numerical analysis of control problems. It is remarkable that optimal control is a challenge for researchers with backgrounds in related fields such as the theory of systems of nonlinear PDEs, numerical methods for solving them, large scale nonlinear optimization, or the numerical simulation and optimization of complex processes in engineering or medical science. This diversity was reflected by the conference program. Talks were focused on âą applications of optimal control to the thermistor problem, crystal growth, quantum mechanics or aviation âą state-constrained optimal control problems âą controllability and observability of the Navier-Stokes equations and of systems for fluid-structure interaction; feedback control âą Hamilton-Bellman-Jacobi equations âą models for the interaction of electromagnetic fields, heat transport and fluid flow âą mesh adaptivity, a-posteriori and a-priori error estimates for the solutions of optimal control problems âą the application of numerical techniques such as semismooth Newton methods, multilevel techniques or domain decomposition âą firstand second-order optimality conditions for the optimal controls of nonlinear systems of PDEs arising from different applications âą modal control âą the optimal shape design of electromagnetic systems or thin shells and on free material optimization. All these issues are currently subject of active research. In extensive and lively discussions, the participants of the workshop produced new mathematical ideas and tightened connections of joint cooperation.