Abstract
Electrifying public bus transportation is a critical step in reaching net-zero goals. In this paper, the focus is on the problem of optimal scheduling of an electric bus (EB) fleet to cover a public transport timetable. The problem is modelled using a mixed integer program (MIP) in which the charging time of an EB is pertinent to the battery’s state-of-charge level. To be able to solve large problem instances corresponding to real-world applications of the model, a metaheuristic approach is investigated. To be more precise, a greedy randomized adaptive search procedure (GRASP) algorithm is developed and its performance is evaluated against optimal solutions acquired using the MIP. The GRASP algorithm is used for case studies on several public transport systems having various properties and sizes. The analysis focuses on the relation between EB ranges (battery capacity) and required charging rates (in kW) on the size of the fleet needed to cover a public transport timetable. The results of the conducted computational experiments indicate that an increase in infrastructure investment through high speed chargers can significantly decrease the size of the necessary fleets. The results also show that high speed chargers have a more significant impact than an increase in battery sizes of the EBs.
Highlights
The first one is to evaluate the effectiveness of the proposed mixed integer program (MIP) and greedy randomized adaptive search procedure (GRASP) for the newly proposed problem
The addressed problem consists of scheduling electric bus (EB) to perform all the trips in a public transport timetable
A GRASP algorithm has been created that can solve problem instances that correspond to urban public transport systems
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. In the VSP, the goal is to optimize the assignment of a set of scheduled trips to a set of vehicles, where each trip is associated with one vehicle, based on some cost function frequently related to the number of used buses This problem becomes significantly harder to solve in case of EBs due to additional constraints related to the range and the scheduling of the charging. These new issues are frequently modeled using the electric vehicle scheduling problem (E-VSP) [16] and its variations.
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