Abstract
The Two Level Network Design (TLND) problem arises when local broadband access networks are planned in areas, where no existing infrastructure can be used, i.e., in the so-called greenfield deployments. Mixed strategies of Fiber-To-The-Home and Fiber-To-The-Curb, i.e., some customers are served by copper cables, some by fiber optic lines, can be modeled by an extension of the TLND. We are given two types of customers (primary and secondary), an additional set of Steiner nodes and fixed costs for installing either a primary or a secondary technology on each edge. The TLND problem seeks a minimum cost connected subgraph obeying a tree-tree topology, i.e., the primary nodes are connected by a rooted primary tree; the secondary nodes can be connected using both primary and secondary technology. In this paper we study an important extension of TLND in which additional transition costs need to be paid for intermediate facilities placed at the transition nodes, i.e., nodes where the change of technology takes place. The introduction of transition node costs leads to a problem with a rich structure permitting us to put in evidence reformulation techniques such as modeling in higher dimensional graphs (which in this case are based on a node splitting technique). We first provide a compact way of modeling intermediate facilities. We then present several generalizations of the facility-based inequalities involving an exponential number of constraints. Finally we show how to model the problem in an extended graph based on node splitting. Our main result states that the connectivity constraints on the splitted graph, projected back into the space of the variables of the original model, provide a new family of inequalities that implies, and even strictly dominates, all previously described cuts. We also provide a polynomial time separation algorithm for the more general cuts by calculating maximum flows on the splitted graph. We compare the proposed models both theoretically and computationally.
This is a preview of subscription content, log in via an institution to check access.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
Preview
Unable to display preview. Download preview PDF.
Similar content being viewed by others
References
Balakrishnan, A., Magnanti, T.L., Mirchandani, P.: A dual-based algorithm for multi-level network design. Management Science 40(5), 567–581 (1994)
Balakrishnan, A., Magnanti, T.L., Mirchandani, P.: Modeling and heuristic worst-case performance analysis of the two-level network design problem. Management Science 40(7), 846–867 (1994)
Chopra, S., Gorres, E.R., Rao, M.R.: Solving the Steiner Tree Problem on a Graph Using Branch and Cut. INFORMS Journal on Computing 4(3), 320–335 (1992)
Costa, A.M., França, P.M., Lyra Filho, C.: Two-level network design with intermediate facilities: An application to electrical distribution systems. Omega 39(1), 3–13 (2011)
Current, J.R., ReVelle, C.S., Cohon, J.L.: The hierarchical network design problem. European Journal of Operational Research 27(1), 57–66 (1986)
Duin, C., Volgenant, T.: The multi-weighted Steiner tree problem. Annals of Operations Research 33(6), 451–469 (1991)
Gollowitzer, S., Ljubić, I.: MIP models for connected facility location: A theoretical and computational study. Computers & Operations Research 38(2), 435–449 (2011)
Gourdin, E., Labbé, M., Yaman, H.: Telecommunication and location - a survey. In: Drezner, Z., Hamacher, H. (eds.) Facility Location: Applications and Theory. Springer, Heidelberg (2001)
Gouveia, L., Janssen, E.: Designing reliable tree networks with two cable technologies. European Journal of Operational Research 105(3), 552–568 (1998)
Gouveia, L., Telhada, J.: The multi-weighted Steiner tree problem: A reformulation by intersection. Computers & Operations Research 35(11), 3599–3611 (2008)
Gouveia, L., Telhada, J.: Distance-constrained hierarchical networks. In: Proceedings of International Network Optimization Conference, INOC 2005, pp. B2.416–B2.421 (2005)
Gurobi: Gurobi Optimization, http://www.gurobi.com/
Jongh, A.D., Gendreau, M., Labbé, M.: Finding disjoint routes in telecommunications networks with two technologies. Operations Research 47(1), 81–92 (1999)
Khoury, B.N., Pardalos, P.M., Du, D.Z.: A test problem generator for the Steiner problem in graphs. ACM Trans. Math. Softw. 19(4), 509–522 (1993)
Koch, T., Martin, A., Voß, S.: SteinLib: An updated library on steiner tree problems in graphs. Tech. rep., Konrad-Zuse-Zentrum für Informationstechnik Berlin (2000), http://elib.zib.de/steinlib
Ljubić, I., Gollowitzer, S.: Modeling the hop constrained connected facility location problem on layered graphs. In: Proceedings of the International Symposium on Combinatorial Optimization (ISCO). Electronic Notes in Discrete Mathematics, vol. 36, pp. 207–214 (2010)
Magnanti, T., Wolsey, L.: Optimal trees. In: Handbook in Operations Research and Management Science, pp. 503–615 (1995)
Author information
Authors and Affiliations
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2011 Springer-Verlag Berlin Heidelberg
About this paper
Cite this paper
Gollowitzer, S., Gouveia, L., Ljubić, I. (2011). A Node Splitting Technique for Two Level Network Design Problems with Transition Nodes. In: Pahl, J., Reiners, T., Voß, S. (eds) Network Optimization. INOC 2011. Lecture Notes in Computer Science, vol 6701. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-21527-8_8
Download citation
DOI: https://doi.org/10.1007/978-3-642-21527-8_8
Publisher Name: Springer, Berlin, Heidelberg
Print ISBN: 978-3-642-21526-1
Online ISBN: 978-3-642-21527-8
eBook Packages: Computer ScienceComputer Science (R0)