Robust network design in telecommunications under polytope demand uncertainty

Robust network design in telecommunications under polytope demand uncertainty

We consider a model for robust network design in telecommunications, in which we minimize the cost of the maximum mismatch between supply and demand. In the present study, the demand is uncertain and takes its values in a polytope defined by constraints. This problem is hardly tractable, so we limit...

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Veröffentlicht in:European journal of operational research 2010-11, Vol.206 (3), p.634-641
Hauptverfasser: Lemaréchal, Claude, Ouorou, Adam, Petrou, Georgios
Format: Artikel
Sprache:eng
Schlagworte:
65K05
65K05 90C25 90C27 Telecommunication network design Polyhedral uncertainty Robust optimization Min-max-min problems
90C25
90C27
Applied sciences
Communications networks
Computer science
control theory
systems
Computer systems and distributed systems. User interface
Cost reduction
Demand
Exact sciences and technology
Flows in networks. Combinatorial problems
Inventory control, production control. Distribution
Marketing
Mathematical analysis
Mathematical models
Min–max–min problems
Networks
Operational research and scientific management
Operational research. Management science
Optimization algorithms
Polyhedral uncertainty
Polytopes
Robust optimization
Software
Studies
Telecommunication network design
Telecommunications
Uncertainty
Upper bounds
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Beschreibung
Zusammenfassung:We consider a model for robust network design in telecommunications, in which we minimize the cost of the maximum mismatch between supply and demand. In the present study, the demand is uncertain and takes its values in a polytope defined by constraints. This problem is hardly tractable, so we limit ourselves to computing lower bounds (by a column-generation mechanism) and upper bounds (using an algorithm due to Falk and Soland for maximizing a separable convex function over a polytope). The experimental gap obtained turns out to be large, and this seems to be mainly due to poor upper bounds. Two possible solutions are suggested for further research aimed at improving them: dc optimization (to minimize the difference of two convex functions) and AARC modeling (affinely adjustable robust counterpart).
ISSN:0377-2217
1872-6860
DOI:10.1016/j.ejor.2010.03.007