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Clique partitioning of interval graphswith submodular costs on the cliques

Published online by Cambridge University Press:  21 August 2007

Dion Gijswijt
Affiliation:
Dep. of Operations Research, EGRES, Eötvös Lorand University, Pázmány Peter Setany. 1/C, 1117 Budapest, Hungary; [email protected]
Vincent Jost
Affiliation:
CNRS, laboratoire Leibniz-IMAG, 46 avenue Félix Viallet, 38031 Grenoble Cedex, France; [email protected]
Maurice Queyranne
Affiliation:
CNRS, laboratoire Leibniz-IMAG, 46 avenue Félix Viallet, 38031 Grenoble Cedex, France; [email protected]
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Abstract

Given a graph G = (V,E) and a “cost function” $f: 2^V\rightarrow\mathbb{R}$ (provided by an oracle), the problem [PCliqW] consists in finding a partition into cliques of V(G) of minimum cost. Here, the cost of a partition is the sum of the costs of the cliques in the partition.We provide a polynomial time dynamic program for the case where G is an interval graph and f belongs to a subclass of submodular set functions, which we call “value-polymatroidal”.This provides a common solution for various generalizations of the coloringproblem in co-interval graphs such as max-coloring,“Greene-Kleitman's dual”, probabilist coloring and chromatic entropy. In the last two cases, this is the first polytime algorithm for co-interval graphs. In contrast, NP-hardness of related problems is discussed. We also describe an ILP formulation for [PCliqW] which gives a common polyhedral framework to express min-max relations such as ${\overline{\chi}}=\alpha$ for perfect graphs and the polymatroid intersection theorem. This approach allows to provide a min-max formula for [PCliqW] if G is the line-graph of a bipartite graph and f is submodular.However, this approach fails to provide a min-max relation for [PCliqW] if G is an interval graphs and f is value-polymatroidal.

Type
Research Article
Copyright
© EDP Sciences, ROADEF, SMAI, 2007

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References

Alon, N. and Orlitsky, A., Source coding and graph entropies. IEEE Trans Inform Theory 42 (1996) 13291339. CrossRef
L. Becchetti, P. Korteweg, A. Marchetti-Spaccamela, M. Skutella, L. Stougie and A. Vitaletti, Latency contrained aggregation in sensor networks. Workshop of Combinatorial Optimization, Aussois (2006).
Boudhar, M., Dynamic Scheduling on a Single Batch Processing Machine with Split Compatibility Graphs. J. Math. Model. Algorithms 2 (2003) 1735. CrossRef
P. Brucker and S. Knust, Complexity results of scheduling problems. www.mathematik.uni-osnabrueck.de/research/OR/class/
Cameron, K., A min-max relation for the partial q-colourings of a graph. II: Box perfection. Discrete Math. 74 (1989) 1527. CrossRef
J. Cardinal, S. Fiorini and G. Joret, Minimum entropy coloring. ISAAC, Lect. Notes Comput. Sci. 3827 (2005) 819–828.
F. Della Croce, B. Escoffier, C. Murat and V. Th. Paschos, Probabilistic coloring of bipartite and split graphs. ICCSA'05, Lect. Notes Comput. Sci. 3483 (2005) 202–211 (see also Cahiers du Lamsade No. 218). CrossRef
M. Demange, D. de Werra, J. Monnot and V.T. Paschos, Time slot scheduling of compatible jobs. Cahiers du Lamsade No. 182, (2001), (accepted in J. Scheduling).
E. Desgrippes, Coordination entre la production et la distribution dans une chaîne logistique. Laboratoire GILCO - Grenoble (2005).
Edmonds, J. and Giles, R., A min-max relation for submodular functions on graphs. Ann. Discrete Math. 1 (1977) 185204. CrossRef
B. Escoffier, J. Monnot and V. Th. Paschos, Weighted Coloring: Further Complexity and Approximability Results. ICTCS (2005) 205–214.
G. Finke, V. Jost, M. Queyranne and A. Sebő, Batch processing with interval graph compatibilities between tasks. Cahier du Leibniz No. 108, Laboratoire Leibniz-IMAG, Grenoble (2004) (accepted in Discrete Appl. Math.).
M.C. Golumbic, Algorithmic Graph Theory and Perfect Graphs. Academic Press (1980).
Guan, D.J. and Xuding Zhu, A Coloring Problem for Weighted Graphs. Inf. Process. Lett. 61 (1997) 7781. CrossRef
Herer, Y.T. and Penn, M., Characterizations of natural submodular graphs: A polynomially solvable class of the TSP. Proc. Am. Math. Soc. 123 (1995) 673679.
V. Jost, Ordonnancement chromatique: Polyèdres, Complexité et Classification. Ph.D. thesis, Laboratoire Leibniz-IMAG - UJF - Grenoble (2006).
A. Schrijver, Combinatorial Optimization: Polyhedra and Efficiency. Springer (2003).
Yannakakis, M. and Gavril, F., The maximum k-colorable subgraph problem for chordal graphs. Inf. Process. Lett. 24 (1987) 133137. CrossRef