Model validation and robust stability analysis of the bacterial heat shock response using SOSTOOLS

Author

El-Samad, H. ; Prajna, S. ; Papachristodoulou, A. ; Khammash, M. ; Doyle, J.C.

Author_Institution

Mech. & Environ. Eng., California Univ., Santa Barbara, CA, USA

Volume

4

fYear

2003

fDate

9-12 Dec. 2003

Firstpage

3766

Abstract

The complexity inherent in gene regulatory network models, as well as their nonlinear nature make them difficult to analyze or validate/invalidate using conventional tools. Combining ideas from robust control theory, real algebraic geometry, optimization and semi-definite programming, SOSTOOLS provides a promising framework to answer these robustness and model validation questions algorithmically. We adopt these tools in the study of the heat shock response in bacteria. For this purpose, we use a reduced order model of the bacterial heat stress response. We study the robust stability properties of this system to parametric uncertainty, and address the model validation/invalidation problem by proving the necessity for the existence of certain feedback loops to reproduce the known time behavior of the system.

Keywords

mathematical programming; microorganisms; polynomials; robust control; software packages; SOSTOOLS; algebraic geometry; bacterial heat shock response; bacterial heat stress response; feedback loops; gene regulatory network models; model invalidation problem; model validation analysis; model validation problem; optimization; parametric uncertainty; reduced order model; robust control theory; robust stability analysis; semidefinite programming; Electric shock; Feedback loop; Geometry; Microorganisms; Reduced order systems; Robust control; Robust stability; Solid modeling; Stress; Uncertainty;

fLanguage

English

Publisher

ieee

Conference_Titel

Decision and Control, 2003. Proceedings. 42nd IEEE Conference on

ISSN

0191-2216

Print_ISBN

0-7803-7924-1

Type

conf

DOI

10.1109/CDC.2003.1271735

Filename

1271735