Fluid dynamical systems as Hamiltonian boundary control systems

Author

van der Schaft, A.J. ; Maschke, B.M.

Author_Institution

Fac. of Math. Sci., Twente Univ., Enschede, Netherlands

Volume

5

fYear

2001

fDate

2001

Firstpage

4497

Abstract

It is shown how the geometric framework for distributed-parameter port-controlled Hamiltonian systems can be adapted to formulate ideal isentropic compressible fluids with nonzero energy flow through the boundary of the spatial domain as Hamiltonian boundary control systems. The key ingredient is the modification of the Stokes-Dirac structure to a Dirac structure defined on the space of mass density 3-forms and velocity 1-forms, incorporating three-dimensional convection. Some initial steps towards stabilization of these boundary control systems, based on the generation of Casimir functions for the closed-loop Hamiltonian system, are discussed

Keywords

boundary layers; closed loop systems; compressible flow; distributed parameter systems; flow; flow control; stability; 3D convection; Casimir functions; Dirac structure; Hamiltonian boundary control systems; Stokes-Dirac structure modification; closed-loop Hamiltonian system; distributed-parameter port-controlled Hamiltonian systems; fluid dynamical systems; geometric framework; ideal isentropic compressible fluids; mass density 3-forms; nonzero energy flow; stabilization; velocity 1-forms; Boundary conditions; Control system synthesis; Control systems; Equations; Fluid dynamics; Fluid flow control; Power system interconnection; Power system modeling; Shape control; Solid modeling;

fLanguage

English

Publisher

ieee

Conference_Titel

Decision and Control, 2001. Proceedings of the 40th IEEE Conference on

Conference_Location

Orlando, FL

Print_ISBN

0-7803-7061-9

Type

conf

DOI

10.1109/.2001.980911

Filename

980911