Title :
Upwind approximations and mesh independence for LQR control of convection diffusion equations
Author :
Burns, John A. ; Zietsman, Lizette
Author_Institution :
Virginia Tech., Blacksburg
Abstract :
The development of practical computational schemes for optimization and control of non-normal distributed parameter systems requires that one builds certain computational efficiencies (such as mesh independence) into the approximation scheme. We consider some numerical issues concerning the application of Kleinman-Newton algorithms to discretizations of infinite dimensional Riccati equations that arise in control of PDE systems. We show that dual convergence and compactness play central roles in both convergence and mesh independence and we present numerical results to illustrate the theory.
Keywords :
Newton method; Poisson equation; Riccati equations; approximation theory; convergence of numerical methods; distributed parameter systems; linear quadratic control; multidimensional systems; partial differential equations; Kleinman-Newton algorithms; LQR control; PDE systems; convection diffusion equations; infinite dimensional Riccati equations; mesh independence; nonnormal distributed parameter systems; upwind approximations; Computational efficiency; Control systems; Convergence of numerical methods; Distributed computing; Distributed control; Distributed parameter systems; Finite element methods; Piecewise linear approximation; Riccati equations; USA Councils;
Conference_Titel :
Decision and Control, 2007 46th IEEE Conference on
Conference_Location :
New Orleans, LA
Print_ISBN :
978-1-4244-1497-0
Electronic_ISBN :
0191-2216
DOI :
10.1109/CDC.2007.4434454
