Reference:
A. Jamshidnejad,
D. Sun,
A. Ferrara, and
B. De Schutter,
"A novel bi-level temporally-distributed MPC approach: An application
to green urban mobility," Transportation Research Part C,
vol. 156, p. 104334, Nov. 2023.
Abstract:
Model predictive control (MPC) has been widely used for traffic
management, such as for minimizing the total time spent or the total
emissions of vehicles. When long-term green urban mobility is
considered including e.g. a constraint on the total yearly emissions,
the optimization horizon of the MPC problem is significantly larger
than the control sampling time, and thus the number of the variables
that should be optimized per control time step becomes very large. For
systems with dynamics that involve nonlinear, non-convex, and
non-smooth functions, including urban traffic networks, this results
in optimization problems that are computationally intractable in real
time. In this paper, we propose a novel bi-level temporal distribution
of such complex MPC optimization problems, and we develop two
mathematically linked short-term and long-term MPC formulations with
small and large control sampling times that will be solved together
instead of the original complex optimization problem. The resulting
bi-level control architecture is used to solve the two MPC
formulations online for real-time control of urban traffic networks
with the objective of long-term green mobility. In order to assess the
performance of the bi-level control architecture, we perform a case
study where a rough version of the model of the urban traffic flow,
S-model, is used by the long-term MPC level to estimate the states of
the urban traffic networks, and a detailed version of the model is
used by the short-term MPC level. The results of the simulations prove
the effectiveness (with respect to the objective of control, as well
as computational efficiency) of the proposed bi-level MPC approach,
compared to state-of-the-art control approaches.