Abstract
We address the operational management of station-based bike sharing systems (BSSs). In BSSs, users can spontaneously rent and return bikes at any stations in the system. Demand is driven by commuter, shopping, and leisure activities. This demand constitutes a regular pattern of bike usage over the course of the day but also shows a significant short-term uncertainty. Due to the heterogeneity and the uncertainty in demand, stations may run out of bikes or congest during the day. At empty stations, no rental demand can be served. At full stations, no return demand can be served. To avoid unsatisfied demand, providers dynamically relocate bikes between stations in reaction of current shortages or congestion, but also in anticipation of potential future demand. For this real-time decision problem, we present a method that anticipates potential future demands based on historical observations and that coordinates the fleet of vehicles accordingly. We apply our method for two case studies based on real-world data of the BSSs in Minneapolis and San Francisco. We show that our policy outperforms benchmark policies from the literature. Moreover, we analyze how the interplay between anticipation and coordination is essential for the successful operational management of BSSs. Finally, we reveal that the value of coordination and anticipation based on the demand-structure of the BSS under consideration.
Highlights
In many cities, station-based bike sharing systems (BSSs) have been proven to be a healthy and flexible alternative to individual travel by car and a suitable complement to public transportation (Buttner et al 2011)
We address the operational management of station-based bike sharing systems (BSSs)
We see that anticipation is more important for San Francisco while coordination is more important for Minneapolis: the difference between short-term relocation policy (STR) and coordinated lookahead policy (CLA) is significantly higher for San Francisco while the difference between CLA-NC and CLA is significantly higher for Minneapolis
Summary
Station-based bike sharing systems (BSSs) have been proven to be a healthy and flexible alternative to individual travel by car and a suitable complement to public transportation (Buttner et al 2011). BSSs are often used for commuting as well as for leisure and shopping activities This leads to imbalances between stations and in the worst case to failed demand in terms of bikes and bike racks causing customer loss on the long run. A dispatcher dynamically routes a fleet of vehicles relocating bikes between the stations. The respective model can be described as multi-vehicle stochastic and dynamic inventory routing problem (SDIRP). Several vehicles may follow the same control policy and approach the same station. We present a method that coordinates the fleet of vehicles in the city. Based on the fleet information, the station an individual vehicle is sent to is determined by means of an assignment problem solution.
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