Balancing the stations of a self service "bike hire" system

Mike Benchimol; Pascal Benchimol; Benoît Chappert; Arnaud De La Taille; Fabien Laroche; Frédéric Meunier; Ludovic Robinet

doi:10.1051/ro/2011102

Balancing the stations of a self service "bike hire" system

Mike Benchimol
, Pascal Benchimol
, Benoît Chappert
, Arnaud De La Taille
, Fabien Laroche
, Frédéric Meunier
, Ludovic Robinet

Université Paris Est, ENPC LIGM, IMAGINE

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

This paper is motivated by operating self service transport systems that flourish nowadays. In cities where such systems have been set up with bikes, trucks travel to maintain a suitable number of bikes per station. It is natural to study a version of the C-delivery TSP defined by Chalasani and Motwani in which, unlike their definition, C is part of the input: each vertex v of a graph G=(V,E) has a certain amount x_v of a commodity and wishes to have an amount equal to y_v (we assume that $\sum-{v\in V}x-v=\sum-{v\in V}y-v$ and all quantities are assumed to be integers); given a vehicle of capacity C, find a minimal route that balances all vertices, that is, that allows to have an amount y_v of the commodity on each vertex v. This paper presents among other things complexity results, lower bounds, approximation algorithms, and a polynomial algorithm when G is a tree.

langue originale	Anglais
Pages (de - à)	37-61
Nombre de pages	25
journal	RAIRO - Operations Research
Volume	45
Numéro de publication	1
Les DOIs	https://doi.org/10.1051/ro/2011102
état	Publié - 1 janv. 2011

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10.1051/ro/2011102

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title = "Balancing the stations of a self service {"}bike hire{"} system",

abstract = "This paper is motivated by operating self service transport systems that flourish nowadays. In cities where such systems have been set up with bikes, trucks travel to maintain a suitable number of bikes per station. It is natural to study a version of the C-delivery TSP defined by Chalasani and Motwani in which, unlike their definition, C is part of the input: each vertex v of a graph G=(V,E) has a certain amount xv of a commodity and wishes to have an amount equal to yv (we assume that \$\textbackslash{}sum-\{v\textbackslash{}in V\}x-v=\textbackslash{}sum-\{v\textbackslash{}in V\}y-v\$ and all quantities are assumed to be integers); given a vehicle of capacity C, find a minimal route that balances all vertices, that is, that allows to have an amount yv of the commodity on each vertex v. This paper presents among other things complexity results, lower bounds, approximation algorithms, and a polynomial algorithm when G is a tree.",

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AU - Benchimol, Pascal

AU - Chappert, Benoît

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AU - Laroche, Fabien

AU - Meunier, Frédéric

AU - Robinet, Ludovic

PY - 2011/1/1

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N2 - This paper is motivated by operating self service transport systems that flourish nowadays. In cities where such systems have been set up with bikes, trucks travel to maintain a suitable number of bikes per station. It is natural to study a version of the C-delivery TSP defined by Chalasani and Motwani in which, unlike their definition, C is part of the input: each vertex v of a graph G=(V,E) has a certain amount xv of a commodity and wishes to have an amount equal to yv (we assume that $\sum-{v\in V}x-v=\sum-{v\in V}y-v$ and all quantities are assumed to be integers); given a vehicle of capacity C, find a minimal route that balances all vertices, that is, that allows to have an amount yv of the commodity on each vertex v. This paper presents among other things complexity results, lower bounds, approximation algorithms, and a polynomial algorithm when G is a tree.

AB - This paper is motivated by operating self service transport systems that flourish nowadays. In cities where such systems have been set up with bikes, trucks travel to maintain a suitable number of bikes per station. It is natural to study a version of the C-delivery TSP defined by Chalasani and Motwani in which, unlike their definition, C is part of the input: each vertex v of a graph G=(V,E) has a certain amount xv of a commodity and wishes to have an amount equal to yv (we assume that $\sum-{v\in V}x-v=\sum-{v\in V}y-v$ and all quantities are assumed to be integers); given a vehicle of capacity C, find a minimal route that balances all vertices, that is, that allows to have an amount yv of the commodity on each vertex v. This paper presents among other things complexity results, lower bounds, approximation algorithms, and a polynomial algorithm when G is a tree.

KW - Approximation algorithm

KW - Routing problem

KW - Self service transport system

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Balancing the stations of a self service "bike hire" system

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