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In the mathematical area of graph theory, an undirected graph G is dually chordal if the hypergraph of its maximal cliques is a hypertree. The name comes from the fact that a graph is chordal if and only if the hypergraph of its maximal cliques is the dual of a hypertree. Originally, these graphs were defined by maximum neighborhood orderings and have a variety of different characterizations.[1] Unlike for chordal graphs, the property of being dually chordal is not hereditary, i.e., induced subgraphs of a dually chordal graph are not necessarily dually chordal (hereditarily dually chordal graphs are exactly the strongly chordal graphs), and a dually chordal graph is in general not a perfect graph. Dually chordal graphs appeared first under the name HT-graphs.[2]

Characterizations

Dually chordal graphs are the clique graphs of chordal graphs,[3] i.e., the intersection graphs of maximal cliques of chordal graphs.

The following properties are equivalent:[4]

G has a maximum neighborhood ordering.
There is a spanning tree T of G such that any maximal clique of G induces a subtree in T.
The closed neighborhood hypergraph N(G) of G is a hypertree.
The maximal clique hypergraph of G is a hypertree.
G is the 2-section graph of a hypertree.

The condition on the closed neighborhood hypergraph also implies that a graph is dually chordal if and only if its square is chordal and its closed neighborhood hypergraph has the Helly property.

In De Caria & Gutierrez (2012) dually chordal graphs are characterized in terms of separator properties. In Brešar (2003) it was shown that dually chordal graphs are precisely the intersection graphs of maximal hypercubes of graphs of acyclic cubical complexes.

The structure and algorithmic use of doubly chordal graphs is given by Moscarini (1993). These are graphs which are chordal and dually chordal.
Recognition

Dually chordal graphs can be recognized in linear time, and a maximum neighborhood ordering of a dually chordal graph can be found in linear time.[5]
Complexity of problems

While some basic problems such as maximum independent set, maximum clique, coloring and clique cover remain NP-complete for dually chordal graphs, some variants of the minimum dominating set problem and Steiner tree are efficiently solvable on dually chordal graphs (but Independent Domination remains NP-complete).[6] See Brandstädt, Chepoi & Dragan (1999) for the use of dually chordal graph properties for tree spanners, and see Brandstädt, Leitert & Rautenbach (2012) for a linear time algorithm of efficient domination and efficient edge domination on dually chordal graphs.
Notes

Brandstädt et al. (1993); Brandstädt, Chepoi & Dragan (1994); Brandstädt et al. (1994); Brandstädt et al. (1998); Brandstädt, Le & Spinrad (1999)
Dragan (1989); Dragan, Prisacaru & Chepoi (1992); Dragan (1993)
Gutierrez & Oubina (1996); Szwarcfiter & Bornstein (1994)
Brandstädt et al. (1993);Brandstädt, Chepoi & Dragan (1998);Brandstädt et al. (1998); Dragan, Prisacaru & Chepoi (1992); Dragan (1993)
Brandstädt, Chepoi & Dragan (1998);Dragan (1989)

Brandstädt, Chepoi & Dragan (1998); Dragan, Prisacaru & Chepoi (1992); Dragan (1993)

References

Brandstädt, Andreas; Chepoi, Victor; Dragan, Feodor (1998), "The algorithmic use of hypertree structure and maximum neighborhood orderings", Discrete Applied Mathematics, 82: 43–77, doi:10.1016/s0166-218x(97)00125-x.
Brandstädt, Andreas; Chepoi, Victor; Dragan, Feodor (1999), "Distance approximating trees for chordal and dually chordal graphs", Journal of Algorithms, 30: 166–184, doi:10.1006/jagm.1998.0962.
Brandstädt, Andreas; Dragan, Feodor; Chepoi, Victor; Voloshin, Vitaly (1993), "Dually Chordal Graphs", Lecture Notes in Computer Science, 790: 237–251.
Brandstädt, Andreas; Dragan, Feodor; Chepoi, Victor; Voloshin, Vitaly (1998), "Dually Chordal Graphs", SIAM Journal on Discrete Mathematics, 11: 437–455, doi:10.1137/s0895480193253415.
Brandstädt, Andreas; Le, Van Bang; Spinrad, Jeremy (1999), Graph Classes: A Survey, SIAM Monographs on Discrete Mathematics and Applications, ISBN 0-89871-432-X.
Brandstädt, Andreas; Leitert, Arne; Rautenbach, Dieter (2012), "Efficient Dominating and Edge Dominating Sets for Graphs and Hypergraphs", Lecture Notes in Computer Science, 7676: 267–277, arXiv:1207.0953.
Brešar, Boštjan (2003), "Intersection graphs of maximal hypercubes", European Journal of Combinatorics, 24: 195–209, doi:10.1016/s0195-6698(02)00142-7.
De Caria, Pablo; Gutierrez, Marisa (2012), "On Minimal Vertex Separators of Dually Chordal Graphs: Properties and Characterizations", Discrete Applied Mathematics, 160: 2627–2635, doi:10.1016/j.dam.2012.02.022.
Dragan, Feodor (1989), Centers of Graphs and the Helly Property (in Russian), Ph.D. thesis, Moldova State University, Moldova.
Dragan, Feodor; Prisacaru, Chiril; Chepoi, Victor (1992), "Location problems in graphs and the Helly property (in Russian)", Discrete Math. (Moscow), 4: 67–73.
Dragan, Feodor (1993), "HT-graphs: centers, connected r-domination and Steiner trees", Comput. Sci. J. of Moldova (Kishinev), 1: 64–83.
Gutierrez, Marisa; Oubina, L. (1996), "Metric Characterizations of proper Interval Graphs and Tree-Clique Graphs", Journal of Graph Theory, 21: 199–205, doi:10.1002/(sici)1097-0118(199602)21:2<199::aid-jgt9>3.0.co;2-m.
McKee, Terry A.; McMorris, FR. (1999), Topics in Intersection Graph Theory, SIAM Monographs on Discrete Mathematics and Applications.
Moscarini, Marina (1993), "Doubly Chordal Graphs, Steiner trees and connected domination", Networks, 23: 59–69, doi:10.1002/net.3230230108.
Szwarcfiter, Jayme L.; Bornstein, Claudson F. (1994), "Clique Graphs of Chordal and Path Graphs", SIAM Journal on Discrete Mathematics, 7: 331–336, CiteSeerX 10.1.1.52.521, doi:10.1137/s0895480191223191.

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