Diffusion Systems: Stability, Modeling, and Identification

Author

Pintelon, R. ; Schoukens, J. ; Pauwels, L. ; Van Gheem, E.

Author_Institution

Vrije Univ. Brussel, Brussels

Volume

2

fYear

2005

fDate

16-19 May 2005

Firstpage

894

Lastpage

899

Abstract

Physical phenomena governed by diffusion (for example, mass or heat transfer) are often better described by rational transfer function models G(radics) in radics, than by rational forms G(s) in the Laplace variable s. A striking difference between both models is that the impulse response of G(s) decreases exponentially to zero, while that of G(radics) decreases algebraically to zero. Hence, transient effects in diffusion phenomena may last long before they can be neglected in, for example, frequency response function measurements. This paper presents an extended transfer function model and an identification algorithm that can handle the slowly decaying transients and, as a consequence, (significantly) reduce the experiment time

Keywords

Laplace equations; diffusion; stability; transfer functions; transient response; Laplace variable; decaying transients; diffusion systems; fractional derivative; frequency response function measurements; impulse response; system identification; transfer functions; Boundary conditions; Differential equations; Disruption tolerant networking; Frequency measurement; Frequency response; Heat transfer; Laplace equations; Partial differential equations; Stability; Transfer functions; diffusion; fractional derivative; frequency domain; impulse response; system identification;

fLanguage

English

Publisher

ieee

Conference_Titel

Instrumentation and Measurement Technology Conference, 2005. IMTC 2005. Proceedings of the IEEE

Conference_Location

Ottawa, Ont.

Print_ISBN

0-7803-8879-8

Type

conf

DOI

10.1109/IMTC.2005.1604264

Filename

1604264