Reference:
R.R. Negenborn,
P.-J. van Overloop,
T. Keviczky, and
B. De Schutter,
"Distributed model predictive control of irrigation canals,"
Networks and Heterogeneous Media, vol. 4, no. 2, pp. 359-380,
June 2009.
Abstract:
Irrigation canals are large-scale systems, consisting of many
interacting components, and spanning vast geographical areas. For safe
and efficient operation of these canals, maintaining the levels of the
water flows close to pre-specified reference values is crucial, both
under normal operating conditions as well as in extreme situations.
Irrigation canals are equipped with local controllers, to control the
flow of water by adjusting the settings of control structures such as
gates and pumps. Traditionally, the local controllers operate in a
decentralized way in the sense that they use local information only,
that they are not explicitly aware of the presence of other
controllers or subsystems, and that no communication among them takes
place. Hence, an obvious drawback of such a decentralized control
scheme is that adequate performance at a system-wide level may be
jeopardized, due to the unexpected and unanticipated interactions
among the subsystems and the actions of the local controllers. In this
paper we survey the state-of-the-art literature on distributed control
of water systems in general, and irrigation canals in particular. We
focus on the model predictive control (MPC) strategy, which is a
model-based control strategy in which prediction models are used in an
optimization to determine optimal control inputs over a given horizon.
We discuss how communication among local MPC controllers can be
included to improve the performance of the overall system. We present
a distributed control scheme in which each controller employs MPC to
determine those actions that maintain water levels after disturbances
close to pre-specified reference values. Using the presented scheme
the local controllers cooperatively strive for obtaining the best
system-wide performance. A simulation study on an irrigation canal
with seven reaches illustrates the potential of the approach.