Skip to main content Accessibility help
×
Hostname: page-component-78c5997874-t5tsf Total loading time: 0 Render date: 2024-11-14T17:59:20.171Z Has data issue: false hasContentIssue false

7 - Perfect graphs

Published online by Cambridge University Press:  05 May 2015

Nicolas Trotignon
Affiliation:
University Paris Diderot
Lowell W. Beineke
Affiliation:
Purdue University, Indiana
Robin J. Wilson
Affiliation:
The Open University, Milton Keynes
Get access

Summary

Perfect graphs were defined by Claude Berge in the 1960s. They are important objects for graph theory, linear programming and combinatorial optimization. Berge made a conjecture about them (now called the strong perfect graph theorem or SPGT) which was proved by Chudnovsky, Robertson, Seymour and Thomas in 2002. This survey about perfect graphs mostly focuses on the SPGT.

Introduction

Every graph G clearly satisfies χ(G) ≥ ω(G), where ω(G) is the clique number of G, because the vertices of a clique must receive different colours. A graph G is perfect if every induced subgraph H of G satisfies χ(H) = ω(H). A chordless cycle of length 2k + 1, for k ≥ 2, satisfies 3 = χ > ω = 2, and its complement satisfies k + 1 = χ > ω = k; these graphs are therefore imperfect. Since perfect graphs are closed under taking induced subgraphs, they must be defined by excluding a family F of graphs as induced subgraphs. The strong perfect graph theorem (SPGT for short) states that the two examples just given are the only members of F.

Let us make this more formal. A hole in a graph G is an induced cycle of length at least 4, and an antihole is a hole of G. A graph is Berge if it does not contain an odd hole or an odd antihole. The following was conjectured by Berge [3] in the 1960s and was the object of much research until it was finally proved in 2002 by Chudnovsky, Robertson, Seymour and Thomas [13].

Theorem 1.1 (Strong perfect graph theorem) A graph is perfect if and only if it is Berge.

One direction of the proof is easy: every perfect graph is Berge since, as we observed above, odd holes and antiholes satisfy χ = ω + 1. The proof of the converse statement is very long and relies on structural graph theory.

Type
Chapter
Information
Publisher: Cambridge University Press
Print publication year: 2015

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

1. N., Alexeev, A., Fradkin and I., Kim, Forbidden induced subgraphs of double-split graphs, SIAMJ. Discrete Math. 26 (2012), 1–14.Google Scholar
2. L. W., Beineke, Characterizations of derived graphs, J. Combin. Theory 9 (1970), 129–135.Google Scholar
3. C., Berge, Färbung von, Graphen, deren sämtliche bzw. deren ungerade Kreise starr sind, Technical report, Wiss. Z. der Martin-Luther-Univ. Halle-Wittenberg, Math.–Natur. Reihe 10, 1961.
4. C., Berge and V., Chvatal (eds.), Topics on Perfect Graphs, Ann. Discrete Math. 21, North-Holland, 1984.
5. J. A., Bondy and U. S. R., Murty, Graph Theory, Graduate Texts in Math. 244, Springer, 2008.Google Scholar
6. A., Brandstadt, V. B., Le and J. P., Spinrad, Graph Classes: A Survey, SIAM, 1999.Google Scholar
7. M., Burlet, F., Maffray and N., Trotignon, Odd pairs of cliques, Graph Theory in Paris, Proc. Conf. in Memory of Claude Berge (eds. A., Bondy et al.), BirkMuser (2007), 85–95.Google Scholar
8. P., Charbit, M., Habib, N., Trotignon and K., Vuskovic, Detecting 2-joins faster, J. Discrete Algorithms 17 (2012), 60–66.Google Scholar
9. M., Chudnovsky, Berge Trigraphs and their Applications, Ph.D. thesis, Princeton University, 2003.Google Scholar
10. M., Chudnovsky, Berge, trigraphs, J. Graph Theory 53 (2006), 1–55.
11. M., Chudnovsky, G., Cornuejols, X., Liu, P., Seymour and K., Vuskovic, Recognizing Berge graphs, Combinatorica 25 (2005), 143–186.Google Scholar
12. M., Chudnovsky, N., Robertson, P., Seymour and R., Thomas, Progress on perfect graphs, Math. Programming (B) 97 (2003), 405–422.Google Scholar
13. M., Chudnovsky, N., Robertson, P., Seymour and R., Thomas, The strong perfect graph theorem, Ann. of Math. 164 (2006), 51–229.Google Scholar
14. M., Chudnovsky and P., Seymour, Excluding induced subgraphs, Surveys in Combinatorics, 2007, London Math. Soc. Lecture Notes 346 (2007), 99–119.Google Scholar
15. M., Chudnovsky and P., Seymour, Even pairs in Berge graphs, J. Combin. Theory (B) 99 (2009), 370–377.Google Scholar
16. M., Chudnovsky and P., Seymour, Three-colourable perfect graphs without even pairs, J. Combin. Theory (B) 102 (2012), 363–394.Google Scholar
17. M., Chudnovsky, N., Trotignon, T., Trunck and K., Vuskovic, Coloring perfect graphs with no balanced skew-partitions, submitted.
18. V., Chvátal, On certain polytopes associated with graphs, J. Combin. Theory (B) 18 (1975), 138–154.Google Scholar
19. V., Chvátal, Star-cutsets and perfect graphs, J. Combin. Theory (B) 39 (1985), 189–199.Google Scholar
20. V., Chvátal and N., Sbihi, Bull-free Berge graphs are perfect, Graphs Combin. 3 (1987), 127–139.Google Scholar
21. M., Conforti, G., Cornuejols, X., Liu, K., Vuskovic and G., Zambelli, Odd hole recognition in graphs of bounded clique size, SIAM J. Discrete Math. 20 (2006), 42–48.Google Scholar
22. M., Conforti, G., Cornuejols and K., Vušković, Square-free perfect graphs, J. Combin. Theory (B) 90 (2004), 257–307.Google Scholar
23. M., Conforti, G., Cornuejols and K., Vuskovic, Decomposition of odd-hole-free graphs by double star cutsets and 2-joins, Discrete Appl. Math. 141 (2004), 41–91.Google Scholar
24. M., Conforti and M. R., Rao, Testing balancedness and perfection of linear matrices, Math. Programming 61 (1993), 1–18.Google Scholar
25. G., Cornuéjols, Combinatorial Optimization: Packing and Covering, CBMS-NSF Regional Conf. Series in Applied Math. 74, SIAM, 2001.Google Scholar
26. G., Cornuéjols and W. H., Cunningham, Composition for perfect graphs, Discrete Math. 55 (1985), 245–254.Google Scholar
27. E., Diot, S., Tavenas and N., Trotignon, Detecting wheels, Analysis Discrete Math. 8 (2014), 111–122.Google Scholar
28. Y., Faenza, G., Oriolo and G., Stauffer, An algorithmic decomposition of claw-free graphs leading to an O(n3)-algorithm for the weighted stable set problem, SODA (2011), 630–646.
29. J., Fonlupt and J. P., Uhry, Transformations which preserve perfectness and h-perfectness of graphs, Bonn Workshop on Combinatorial Optimization (eds. A., Bachem, M., Grötschel and B., Korte), Ann. Discrete Math. 16 (1982), 83–85.Google Scholar
30. D. R., Fulkerson, Anti-blocking polyhedra, J. Combin. Theory (B) 12 (1972), 50–71.Google Scholar
31. T., Gallai, Transitiv orientierbare Graphen, Acta Math. Acad. Sci. Hungar. 18 (1967), 25–66.Google Scholar
32. G. S., Gasparian, Minimal imperfect graphs: a simple approach, Combinatorica 16 (1996), 209–212.Google Scholar
33. M. C., Golumbic, Algorithmic Graph Theory and Perfect Graphs, Elsevier, 2004.Google Scholar
34. M., Gröstchel, L., Lovász and A., Schrijver, Geometric Algorithms and Combinatorial Optimization, Springer-Verlag, 1988.Google Scholar
35. A., Gyárfás, Problems from the world surrounding perfect graphs, Zastowania Mat. Appl. Math. 19 (1987), 413–441.Google Scholar
36. A., Gyárfás, Z., Li, R. C. S., Machado, A., Sebő, S., Thomassé and N., Trotignon, Complements of nearly perfect graphs, J. Combin. 4 (2013), 299–310.Google Scholar
37. M., Habib, A., Mamcarz and F., de Montgolfier, Algorithms for some H-join decompositions, LATIN 2012, 446–457.
38. S., Hougardy, Classes of perfect graphs, Discrete Math. 306 (2006), 2529–2571.Google Scholar
39. W. S., Kennedy and B., Reed, Fast Skew Partition Recognition, Lecture Notes in Computer Science 4535 (2008), 101–107.Google Scholar
40. P. G. H., Lehot, An optimal algorithm to detect a line graph and output its root graph, J. Assoc. Comp. Mach. 21 (1974), 569–575.Google Scholar
41. B., Lévêque and D., de Werra, Graph transformations preserving the stability number, Discrete Appl. Math. 160 (2012), 2752–2759.Google Scholar
42. B., Lévêque, F., Maffray, B., Reed and N., Trotignon, Coloring Artemis graphs, Theor. Comp. Sci. 410 (2009), 2234–2240.Google Scholar
43. L., Lovász, A characterization of perfect graphs, J. Combin. Theory (B) 13 (1972), 95–98.Google Scholar
44. L., Lovász, Normal hypergraphs and the perfect graph conjecture, Discrete Math. 2 (1972), 253–267.Google Scholar
45. L., Lovász, Perfect graphs, Selected Topics in Graph Theory (eds. L. W., Beineke and R. J., Wilson), Academic Press (1983), 55–87.Google Scholar
46. F., Maffray, Fast recognition of doubled graphs, Technical Report, Les Cahiers Leibniz 202, 2013.
47. F., Maffray and N., Trotignon, Algorithms for perfectly contractile graphs, SIAM J. Discrete Math. 19 (2005), 553–574.Google Scholar
48. F., Maffray and N., Trotignon, A class of perfectly contractile graphs, J. Combin. Theory (B) 96 (2006), 1–19.Google Scholar
49. H., Meyniel, A new property of critical imperfect graphs and some consequences, Europ. J. Combin. 8 (1987), 313–316.Google Scholar
50. J. L. Ramírez, Alfonsín and B. A., Reed (eds.), Perfect Graphs, Wiley Interscience, 2001.
51. B. A., Reed, Skew partitions in perfect graphs, Discrete Appl. Math. 156 (2008), 1150–1156.Google Scholar
52. F., Roussel and P., Rubio, About skew partitions in minimal imperfect graphs, J. Combin. Theory (B) 83 (2001), 171–190.Google Scholar
53. F., Roussel, I., Rusu and H., Thuillier, The Strong Perfect Graph Conjecture: 40 years of attempts and its resolution, Discrete Math. 309 (2009), 6092–6113.Google Scholar
54. N. D., Roussopoulos, A max {m, n} algorithm for determining the graph H from its line graph G, Inform. Proc. Letters 2 (1973), 108–112.Google Scholar
55. A., Schrijver, Combinatorial Optimization, Polyhedra and Efficiency, Springer, 2003.Google Scholar
56. P., Seymour, How the proof of the strong perfect graph conjecture was found, Gazette des Math. 109 (2006), 69–83.Google Scholar
57. N., Trotignon, Decomposing Berge graphs and detecting balanced skew partitions, J. Combin. Theory (B) 98 (2008), 173–225.Google Scholar
58. N., Trotignon and K., Vušković, On Roussel–Rubio–type lemmas and their consequences, Discrete Math. 311 (2011), 684–687.Google Scholar
59. N., Trotignon and K., Vuskovic, Combinatorial optimization with 2-joins, J. Combin. Theory (B) 102 (2012), 153–185.Google Scholar
60. K., Vušković, The world of hereditary graph classes viewed through Truemper configurations, Surveys in Combinatorics 2013, London Math. Soc. Lecture Notes 409 (2013), 265–326.Google Scholar

Save book to Kindle

To save this book to your Kindle, first ensure coreplatform@cambridge.org is added to your Approved Personal Document E-mail List under your Personal Document Settings on the Manage Your Content and Devices page of your Amazon account. Then enter the ‘name’ part of your Kindle email address below. Find out more about saving to your Kindle.

Note you can select to save to either the @free.kindle.com or @kindle.com variations. ‘@free.kindle.com’ emails are free but can only be saved to your device when it is connected to wi-fi. ‘@kindle.com’ emails can be delivered even when you are not connected to wi-fi, but note that service fees apply.

Find out more about the Kindle Personal Document Service.

Available formats
×

Save book to Dropbox

To save content items to your account, please confirm that you agree to abide by our usage policies. If this is the first time you use this feature, you will be asked to authorise Cambridge Core to connect with your account. Find out more about saving content to Dropbox.

Available formats
×

Save book to Google Drive

To save content items to your account, please confirm that you agree to abide by our usage policies. If this is the first time you use this feature, you will be asked to authorise Cambridge Core to connect with your account. Find out more about saving content to Google Drive.

Available formats
×