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Designing optimal networks for multicommodity transport problem

2021

Article

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Designing and optimizing different flows in networks is a relevant problem in many contexts. While a number of methods have been proposed in the physics and optimal transport literature for the one-commodity case, we lack similar results for the multi-commodity scenario. In this paper we present a model based on optimal transport theory for finding optimal multi-commodity flow configurations on networks. This model introduces a dynamics that regulates the edge conductivities to achieve, at infinite times, a minimum of a Lyapunov functional given by the sum of a convex transport cost and a concave infrastructure cost. We show that the long time asymptotics of this dynamics are the solutions of a standard constrained optimization problem that generalizes the one-commodity framework. Our results provide new insights into the nature and properties of optimal network topologies. In particular, they show that loops can arise as a consequence of distinguishing different flow types, complementing previous results where loops, in the one-commodity case, were obtained as a consequence of imposing dynamical rules to the sources and sinks or when enforcing robustness to damage. Finally, we provide an efficient implementation of our model which convergences faster than standard optimization methods based on gradient descent.

Author(s): Lonardi, Alessandro and Facca, Enrico and Putti, Mario and De Bacco, Caterina
Journal: Physical Review Research
Volume: 3
Number (issue): 4
Pages: 043010
Year: 2021
Month: October

Department(s): Physics for Inference and Optimization
Bibtex Type: Article (article)
Paper Type: Journal

DOI: 10.1103/PhysRevResearch.3.043010
Eprint: https://arxiv.org/abs/2010.14377v2
State: Published

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BibTex

@article{mcopt,
  title = {Designing optimal networks for multicommodity transport problem},
  author = {Lonardi, Alessandro and Facca, Enrico and Putti, Mario and De Bacco, Caterina},
  journal = {Physical Review Research},
  volume = {3},
  number = {4},
  pages = {043010},
  month = oct,
  year = {2021},
  doi = {10.1103/PhysRevResearch.3.043010},
  eprint = {https://arxiv.org/abs/2010.14377v2},
  month_numeric = {10}
}