Abstract
This paper studies a dynamic capacitated arc routing problem for battery replacement in an e-bike sharing system, where workers replace batteries for underpowered e-bikes along street segments dynamically. The objective is to replace as many batteries as possible and minimize pickup failures. The temporal dependency of the routing decisions, the conflict of the workers’ operations, and the stochastic and dynamic nature of user demands all make this a difficult problem. To cope with these difficulties, a “Partition-First, Route-Second” bi-level solution framework is adopted to describe the problem in two different time scales. On the large time scale, a spatiotemporal partitioning method, which divides the road network into nonoverlapping subzones, is proposed to decompose the problem. On the small time scale, this paper models the routing decision process of individual worker as a Markov Decision Process. We adopt a lookahead policy that simulates future information and decisions over some horizons to evaluate the long-term influence of current feasible decisions. A Monte Carlo Tree Search algorithm is also used to improve the simulation efficiency. By performing numerical computation experiments on a test case study and comparing with some benchmarking policies, we demonstrate the effectiveness and efficiency of the suggested method.
Highlights
Erefore, this paper mainly considers a dynamic version of the capacitated arc routing problem (CARP) (DCARP) in E-Bike Sharing System (EBSS): the battery replacement is performed during daytime, when the user’s participation must be considered and new underpowered e-bikes may stochastically appear after the fleet departs from depot
We found that the impact on the success rate of user pickups through battery replacement operation alone is limited because the EBSS has other problems that can affect the success of user pickups, such as the unbalanced distribution of e-bike supply and user demand, which could not be solved by battery replacement operation
We have modeled the battery replacement in an EBSS as a DCARP according to the distribution characteristics of the virtual parking spots. e objective is to maximize a weighted sum of the number of successful pickup demands and the number of batteries replaced
Summary
Decomposing the decision processes of multiple workersAnticipating the long-term influence of current routing decisions.
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