This paper proposes a novel distributed control strategy for the optimal charging of a fleet of Electric Vehicles (EVs) in case of limited overall capacity of the electrical distribution network. The optimal charging is obtained as the solution of a scheduling problem aiming at a cost-optimal profile of the aggregated energy demand. The resulting optimization problem is formulated as a quadratic programming problem with a coupling of decision variables both in the objective function and in the constraint. We assume a minimal information structure, where users locally communicate only with their neighbors, without relying on a central decision maker. The solution approach relies on an iterative distributed algorithm based on duality, proximity, and consensus theory. A simulated case study demonstrates that the approach allows achieving the global optimum.
A Distributed Control Algorithm for Optimal Charging of Electric Vehicle Fleets with Congestion Management / Carli, Raffaele; Dotoli, Mariagrazia. - ELETTRONICO. - 51:9(2018), pp. 373-378. (Intervento presentato al convegno 15th International-Federation-of-Automatic-Control (IFAC) Symposium on Control in Transportation Systems (CTS) tenutosi a Savona, Italy nel June 6-8, 2018) [10.1016/j.ifacol.2018.07.061].
A Distributed Control Algorithm for Optimal Charging of Electric Vehicle Fleets with Congestion Management
Raffaele Carli;Mariagrazia Dotoli
2018-01-01
Abstract
This paper proposes a novel distributed control strategy for the optimal charging of a fleet of Electric Vehicles (EVs) in case of limited overall capacity of the electrical distribution network. The optimal charging is obtained as the solution of a scheduling problem aiming at a cost-optimal profile of the aggregated energy demand. The resulting optimization problem is formulated as a quadratic programming problem with a coupling of decision variables both in the objective function and in the constraint. We assume a minimal information structure, where users locally communicate only with their neighbors, without relying on a central decision maker. The solution approach relies on an iterative distributed algorithm based on duality, proximity, and consensus theory. A simulated case study demonstrates that the approach allows achieving the global optimum.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
