Reference:
S. Roshany-Yamchi,
R.R. Negenborn,
M. Cychowski,
B. De Schutter,
J. Connell, and
K. Delaney,
"Distributed model predictive control and estimation of large-scale
multi-rate systems," Proceedings of the 18th IFAC World
Congress, Milan, Italy, pp. 416-422, Aug.-Sept. 2011.
Abstract:
In this paper, we propose a new method for control of large-scale
multi-rate systems with linear dynamics that are coupled via inputs.
These systems are multi-rate systems in the sense that either output
measurements or input updates are not available at certain sampling
times. Such systems can arise, e.g., when the number of sensors is
less than the number of variables to be controlled, or when
measurements of outputs cannot be completed simultaneously because of
applicational limitations. The multi-rate nature gives rise to lack of
information, which will cause uncertainty in the system's performance.
A distributed model predictive control (MPC) approach based on Nash
game theory is proposed to control multi-agent multi-rate systems in
which multiple control agents each determine actions for their own
parts of the system. Via communication, the agents can in a
cooperative way take one another's actions into account. To compensate
for the information loss due to the multi-rate nature of the systems
under study, a distributed Kalman Filter is proposed to provide the
optimal estimation of the missing information. Using simulation
studies on a distillation column the added value of the proposed
distributed MPC and Kalman Filter method is illustrated in comparison
with a centralized MPC with centralized Kalman Filter, and a
distributed MPC method with a fully decentralized (i.e., no
communication) Kalman Filter.