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Publications of CWI Research Group
Control and System Theory
- Publications by Co-Workers
Co-Workers were post-doctoral researchers and Ph.D. students.
Realization
J.M. van den Hof,
Realization of positive linear systems. Linear Algebra and its Applications 256 (1997), 287-308.
Preprint available as CWI report
BS-R9532, CWI, Amsterdam, December 1995.
J.M. van den Hof, System theory and system identification of compartmental systems.
Ph.D. thesis, University of Groningen, Groningen, 1996.
J.M. van den Hof,
Realization of continuous-time positive linear systems. Systems and Control Letters 31 (1997), 243-253.
System identification
J.M. van den Hof,
Structural identifiability of linear mamillary compartmental
systems. Proceedings of the 3rd European Control Conference,
September 5-8, 1995, Rome, Italy, 1318-1323.
J.M. van den Hof, Structural identifiability from input-output observations of linear compartmental systems.
Report BS-R9514, CWI, Amsterdam, Mei 1995.
J.M. van den Hof, Structural identifiability of linear mamillary compartmental systems.
Report BS-R9512, CWI, Amsterdam, April 1995.
J.M. van den Hof,
Structural identifiability of linear compartmental systems. IEEE Trans. Automatic Control 43 (1998), 800-818.
W. Slob, P.H.M. Janssen, J.M. van den Hof,
Structural identifiability of PBPK models:
Practical consequences for modeling strategies and study designs. Critical Reviews in Toxicology 27 (1997), 261-272.
Positive systems
J.M. van den Hof,
Positive linear observers for linear compartmental systems. SIAM J. Control and Optimization 36 (1998), 590-608.
Control and system theory of biochemical reaction networks
I.W.M. Verburg,
Modeling and control of glycolysis in Trypanosoma brucei.
Master thesis, Department of Mathematics, Vrije Universiteit,
Amsterdam, 2006 March. pdf file of master thesis.
Control of discrete-event systems
A. Overkamp,
Supervisory Control for Nondeterministic Systems.
In G. Cohen and J.-P. Quadrat (Eds.),
11th International Conference on Analysis and Optimization of Systems,
Discrete Event Systems,
Sophia-Antipolis, France, 1994, 59-65.
Also available as CWI report
BS-R9411.
A. Overkamp,
Control of Nondeterministic Discrete Event Systems
using Failure Semantics, Proceedings of the 3rd European Control Conference,
Rome, 1995, 2778-2783.
A. Overkamp,
Supervisory Control using Failure Semantics and Partial
Specifications. IEEE Transactions on Automatic Control 42 (1997), 498-510.
A. Overkamp, Discrete event control motivated by layered network architectures.
Ph.D. thesis, University of Groningen, Groningen, 1996.
Jan Komenda,
Coalgebra and coinduction in decentralized supervisory control, Proceedings of the IFAC CSA 2003 Conference,
(2003), x-y.
J. Komenda, H. Marchand, and S. Pinchinat,
A Constructive and Modular Approach to Decentralized Supervisory Control
Problems,
Proc. 3rd IFAC Workshop on Discrete-Event System Design, DESDes'06,
M. Adamski (Ed.),
2006, 111-116.
(Rydzyna Castle, Poland)
Control of hybrid systems
Mihaly Petreczky,
Realization theory for linear switched systems,
Proc. International Symposium MTNS.2004, Leuven, Belgium, July 2004.
Calin Belta, Luc C.G.J.M. Habets, Vijay Kumar,
Control of multi-affine systems on rectangles with applcations
to hybrid biomolecular networks,
Proc. IEEE Conference on Decision and Control,
December 2002, to appear.
J.J.H. Fey, Control and verification of industrial hybrid systems using
models specified with the formalism Chi.
Note BS-N9601, CWI, Amsterdam, April 1996.