Reference:
R.R. Negenborn,
A. Sahin,
Z. Lukszo,
B. De Schutter, and
M. Morari,
"A non-iterative cascaded predictive control approach for control of
irrigation canals," Proceedings of the 2009 IEEE International
Conference on Systems, Man, and Cybernetics, San Antonio, Texas,
pp. 3652-3657, Oct. 2009.
Abstract:
Irrigation canals transport water from water sources (such as large
rivers and lakes) to water users (such as farmers). Irrigation canals
are typically very large in nature, covering vast geographical areas,
and involving a significant number of control actuators, such as
pumps, gates, and locks. The control of such canals is aimed at
guaranteeing the adequate delivery of water with minimal water
spillage and with minimal control structure usage. To take into
account forecasts on, e.g., water consumption and weather, model
predictive control (MPC) can be used to determine which actions to
take. For large-scale systems, in which different parts of the canal
are owned by different parties, distributed MPC control could then be
employed. Although iterative distributed MPC approaches proposed
earlier in the literature may yield overall optimal performance, the
amount of iterations required before achieving this performance may be
large, and thus require a significant amount of time. In this paper,
the structure of systems consisting of serially interconnected
subsystems is exploited to obtain an efficient non-iterative, cascaded
MPC scheme. Simulation studies on a 7-reach irrigation canal
illustrate the performance of this non-iterative scheme in comparison
with an iterative scheme.