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Aggregation Methods for Railway Network Design Based on Lifted Benders Cuts

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Handbook of Optimization in the Railway Industry

Part of the book series: International Series in Operations Research & Management Science ((ISOR,volume 268))

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Abstract

Rail freight traffic in Germany has experienced significant growth rates over the last decade, and recent forecasts expect this tendency to continue over the next 20 years due to the increases in national and international trade. Internal predictions of Deutsche Bahn AG, the most important German railway enterprise, assume a mean increase of 2% per year for rail freight traffic until 2030. At this pace, the German railway network in its current state would reach its capacity limit way before this date. As investments into the network infrastructure bear a very high price tag, it is crucial to use the available budget in the most efficient manner. Furthermore, the large size of the networks under consideration warrants the development of efficient algorithms to handle the complex network design problems arising for real-world data. This led us to the development of network aggregation procedures which allow for much shorter solution times by compressing the network information. More exactly, our framework works by clustering the nodes of the underlying graph to components and solving the network design problem over this aggregated graph. This kind of aggregation may either be used as a quick heuristic, or it can be extended to an exact method, e.g. by iterative refinement of the clustering, The latter results in a cutting plane algorithm, which also introduces new variables with each refinement. This idea developed in Bärmann et al. (Math Program Comput 7(2):189–217, 2015) is extended in this chapter such that it is able to incorporate the costs for routing flow through the network via lifted Benders optimality cuts. Altogether, our algorithm can be seen as a novel kind of Benders decomposition which allows to shift variables from the subproblem to the master problem in the process. Computations on several benchmark sets demonstrate the effectiveness of the approach.

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Acknowledgements

We thank our co-authors from [1], Alexander Martin, Maximilian Merkert, Christoph Thurner and Dieter Weninger, for the interesting discussions we had on the topic. Furthermore, we gratefully acknowledge the computing resources provided by the group of Michael Jünger in Cologne. In particular, we thank Thomas Lange for his technical support. Last but not least, we thank the BMBF for its financial support under research grant 05M10WEC.

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Authors and Affiliations

  1. Department Mathematik, FAU Erlangen-Nürnberg, Lehrstuhl für Wirtschaftsmathematik, Cauerstraße 11, 91058, Erlangen, Germany

    Andreas Bärmann & Frauke Liers

Authors
  1. Andreas Bärmann
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  2. Frauke Liers
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Correspondence to Andreas Bärmann .

Editor information

Editors and Affiliations

  1. Zuse Institute Berlin & Freie Universität Berlin, Berlin, Germany

    Ralf Borndörfer

  2. Department of Optimization, Zuse Institute Berlin, Berlin, Germany

    Torsten Klug

  3. Optrail, Rome, Italy

    Leonardo Lamorgese

  4. SINTEF DIGITAL & University of Oslo, Oslo, Norway

    Carlo Mannino

  5. LBW Optimization GmbH & Zuse Institute Berlin, Berlin, Germany

    Markus Reuther

  6. LBW Optimization GmbH & Zuse Institute Berlin, Berlin, Germany

    Thomas Schlechte

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Bärmann, A., Liers, F. (2018). Aggregation Methods for Railway Network Design Based on Lifted Benders Cuts. In: Borndörfer, R., Klug, T., Lamorgese, L., Mannino, C., Reuther, M., Schlechte, T. (eds) Handbook of Optimization in the Railway Industry. International Series in Operations Research & Management Science, vol 268. Springer, Cham. https://doi.org/10.1007/978-3-319-72153-8_3

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