Abstract Open-loop and closed-loop control problems for distributed parameter systems, described by parabolic partial differential equations, are considered in this contribution. The goal of the study is the development of strategies for control and estimation of states, disturbances, and parameters. These strategies are based on the method of integrodifferential relations, a projection approach, and a suitable finite element technique. A real-time applicable control algorithm is proposed and its specific features are discussed. A verification of the control laws derived in this contribution is performed taking into account explicit error estimates resulting directly from the integrodifferential approach. The parameters, geometry, and actuation principles of a heat transfer system available at the Chair of Mechatronics, University of Rostock, are used for the numerical simulation and experimental validation. The test setup consists of a metallic rod equipped with a finite number of Peltier elements which are used as distributed control inputs allowing for active cooling and heating.
[1]
Georgy Kostin,et al.
Modeling of controlled motions of an elastic rod by the method of integro-differential relations
,
2006
.
[2]
Andreas Rauh,et al.
Reliable finite-dimensional models with guaranteed approximation quality for control of distributed parameter systems
,
2012,
2012 IEEE International Conference on Control Applications.
[3]
Georgy Kostin,et al.
Approaches to control design and optimization in heat transfer problems
,
2010
.
[4]
Andrey Smyshlyaev,et al.
Adaptive Control of Parabolic PDEs
,
2010
.
[5]
Georgy Kostin,et al.
Adaptive Control Strategies in Heat Transfer Problems with Parameter Uncertainties Based on a Projective Approach
,
2011
.