Robust H∞ Control for Switched Nonlinear Systems with
Application to High-Level Urban Traffic Control
Reference
M. Hajiahmadi,
B. De Schutter, and
H. Hellendoorn,
"Robust H∞ Control for Switched Nonlinear Systems
with Application to High-Level Urban Traffic Control," Proceedings of the 52nd IEEE Conference on Decision and
Control, Florence, Italy, pp. 899-904, Dec. 2013.
Abstract
This paper presents robust switching control strategies for switched
nonlinear systems with constraints on the control inputs. First, a
model transformation is proposed in a way that the constraint on the
continuous control inputs is relaxed. Next, the effect of disturbance
is taken into account and the L2-gain analysis and
H∞ control design problem for switched nonlinear
systems are formulated and proved. Furthermore, the obtained control
laws are utilized for urban traffic networks modeled on a high-level
using macroscopic fundamental diagram representation. The flow
transferred between urban regions along with the timing plans for each
region are controlled using continuous and switching controllers. The
control objective is translated into a stability and disturbance
attenuation problem for the urban network represented as a switched
nonlinear system. The uncertain trip demands are considered as
norm-bounded disturbance inputs. One major advantage of the proposed
scheme is that the parameters of the feedback switching law are
obtained offline. Hence, real-time control is possible with this
scheme. The achieved results show great performance of the proposed
approach in handling uncertain demand profiles.
Downloads
- Corresponding technical report:
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Bibtex entry
@inproceedings{HajDeS:13-039,
author={M. Hajiahmadi and B. {D}e Schutter and H. Hellendoorn},
title={Robust ${H}_{\infty}$ Control for Switched Nonlinear Systems with
Application to High-Level Urban Traffic Control},
booktitle={Proceedings of the 52nd IEEE Conference on Decision and Control},
address={Florence, Italy},
pages={899--904},
month=dec,
year={2013}
}
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