Modeling and solving vehicle routing problems with many available vehicle types
Paper in proceedings, 2015

Vehicle routing problems (VRP) involving the selection of vehicles from a large set of vehicle types are hitherto not well-studied in the literature. Such problems arise at Volvo Group Trucks Technology, who faces an immense set of possible vehicle configurations, of which an optimal set needs to be chosen for each specific combination of transport missions. Another property of real-world VRP’s that is often neglected in the literature is that the fuel resources required to drive a vehicle along a route is highly dependent on the actual load of the vehicle. We define the fleet size and mix VRP with many available vehicle types, called many-FSMVRP, and suggest an extended set-partitioning model of this computationally demanding combinatorial optimization problem. To solve the extended model, we have developed a method based on Benders’ decomposition, the subproblems of which are solved using column generation, and the column generation subproblems being solved using dynamic programming; the method is implemented with a so-called projection-of-routes procedure. The resulting method is compared with a column generation approach for the standard set-partitioning model. Our method for the extended model performs on par with column generation applied to the standard model for instances such that the two models are equivalent. In addition, the utility of the extended model for instances with very many available vehicle types is demonstrated. Our method is also shown to efficiently handle cases in which the costs are dependent on the load of the vehicle. Computational tests on a set of extended standard test instances show that our method, based on Benders’ algorithm, is able to determine combinations of vehicles and routes that are optimal to a relaxation (w.r.t. the route decision variables) of the extended model. Our exact implementation of Benders’ algorithm appears, however, too slow when the number of customers grows. To improve its performance, we suggest that relaxed versions of the column generation subproblems are solved, and that the set-partitioning model is replaced by a set-covering model.

Vehicle routing problem

Benders decomposition

heterogeneous fleet

projection of routes

many vehicle types

set partitioning

fleet size and mix

Author

Sandra Eriksson Barman

SuMo Biomaterials

Chalmers, Mathematical Sciences, Mathematical Statistics

University of Gothenburg

Peter Lindroth

Volvo Group

Ann-Brith Strömberg

Chalmers, Mathematical Sciences, Mathematics

University of Gothenburg

Springer Proceedings in Mathematics & Statistics

2194-1017 (eISSN)

Vol. 130 113-138

Driving Forces

Sustainable development

Areas of Advance

Transport

Subject Categories

Computational Mathematics

Roots

Basic sciences

DOI

10.1007/978-3-319-18567-5_6

ISBN

978-3-319-18566-8

More information

Latest update

11/16/2018