Abstract
In this work, we investigate a new paradigm for dock-less bike sharing. Recently, it has become essential to accommodate connected and free-floating bicycles in modern bike-sharing operations. This change comes with an increase in the coordination cost, as bicycles are no longer checked in and out from bike-sharing stations that are fully equipped to handle the volume of requests; instead, bicycles can be checked in and out from virtually anywhere. In this paper, we propose a new framework for combining traditional bike stations with locations that can serve as free-floating bike-sharing stations. The framework we propose here focuses on identifying highly centralized k-clubs (i.e., connected subgraphs of restricted diameter). The restricted diameter reduces coordination costs as dock-less bicycles can only be found in specific locations. In addition, we use closeness centrality as this metric allows for quick access to dock-less bike sharing while, at the same time, optimizing the reach of service to bikers/customers. For the proposed problem, we first derive its computational complexity and show that it is NP-hard (by reduction from the 3-SATISFIABILITY problem), and then provide an integer programming formulation. Due to its computational complexity, the problem cannot be solved exactly in a large-scale setting, as is such of an urban area. Hence, we provide a greedy heuristic approach that is shown to run in reasonable computational time. We also provide the presentation and analysis of a case study in two cities of the state of North Dakota: Casselton and Fargo. Our work concludes with the cost-benefit analysis of both models (docked vs. dockless) to suggest the potential advantages of the proposed model.
Highlights
Bike-sharing systems (BSSs) have become a prominent mode of transportation around the world, especially in urban areas
In a dock-less BSS, residents that are interested in using a bicycle can check out and in bicycles throughout an urban area using nothing more than their smartphones. e bicycles are equipped with a geographic positioning system (GPS), enabling users to locate the nearest available bicycle and to unlock it with the use of an app
We propose an integer programming formulation and a heuristic algorithm to find the most centralized -club in a transportation network based on closeness centrality. e resultant -club consists of a set of nodes in which the maximum traversing distance is hops, and the total weighted by population distance to a node in the club is minimized
Summary
Bike-sharing systems (BSSs) have become a prominent mode of transportation around the world, especially in urban areas. We propose a framework that will both (i) allow users the increased benefits of a dock-less system (easy and fast access to bicycles, reduced parking space needs) and (ii) reduce the coordination costs for controlling the sprawl of the dock-less bike-sharing operations by restricting the size of the geo-fenced area. E resultant -club consists of a set of nodes in which the maximum traversing distance is hops (by definition), and the total weighted by population distance to a node in the club is minimized (as it will be the -club with maximum closeness centrality) Based on this result, a BSS operator could enable the area covered by the -club as the geo-fenced area where dock-less bike-sharing is allowed and satisfy the following objectives:. To the best of our knowledge, this paper is the first to suggest a solution to problems that have arisen from the emergence of dock-less bike-sharing systems with the aid of a -club. e ultimate goal is to locate potential hubs in a city, referred to as -clubs, by geo-fencing a suitably small area of a city
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