Clique-width

Construction of a distance-hereditary graph of clique-width 3 by disjoint unions, relabelings, and label-joins. Vertex labels are shown as colors.

In graph theory, the clique-width of a graph $G$ is a parameter that describes the structural complexity of the graph; it is closely related to treewidth, but unlike treewidth it can be bounded even for dense graphs. It is defined as the minimum number of labels needed to construct $G$ by means of the following 4 operations :

Creation of a new vertex v with label i ( noted i(v) )
Disjoint union of two labeled graphs G and H ( denoted $G\oplus H$ )
Joining by an edge every vertex labeled i to every vertex labeled j (denoted η(i,j)), where $i\neq j$
Renaming label i to label j ( denoted ρ(i,j) )

Graphs of bounded clique-width include the cographs and distance-hereditary graphs. Although it is NP-hard to compute the clique-width when it is unbounded, and unknown whether it can be computed in polynomial time when it is bounded, efficient approximation algorithms for the clique-width are known. Based on these algorithms and on Courcelle's theorem, many graph optimization problems that are NP-hard for arbitrary graphs can be solved or approximated quickly on the graphs of bounded clique-width.

The construction sequences underlying the concept of clique-width were formulated by Courcelle, Engelfriet, and Rozenberg in 1990^[1] and by Wanke (1994). The name "clique-width" was used for a different concept by Chlebíková (1992). By 1993, the term already had its present meaning.^[2]

Special classes of graphs

Cographs are exactly the graphs with clique-width at most 2.^[3] Every distance-hereditary graph has clique-width at most 3. However, the clique-width of unit interval graphs is unbounded (based on their grid structure).^[4] Similarly, the clique-width of bipartite permutation graphs is unbounded (based on similar grid structure).^[5] Based on the characterization of cographs as the graphs without induced subgraph isomorphic to a chordless path with four vertices, the clique-width of many graph classes defined by forbidden induced subgraphs has been classified.^[6]

Other graphs with bounded clique-width include the $k$ -leaf powers for bounded values of $k$ ; these are the induced subgraphs of the leaves of a tree $T$ in the graph power $T k$ . However, leaf powers with unbounded exponents do not have bounded clique-width.^[7]

Bounds

Courcelle & Olariu (2000) and Corneil & Rotics (2005) proved the following bounds on the clique-width of certain graphs:

If a graph has clique-width at most $k$ , then so does every induced subgraph of the graph.^[8]
The complement graph of a graph of clique-width $k$ has clique-width at most $2 k$ .^[9]
The graphs of treewidth $w$ have clique-width at most $3 \cdot 2 w - 1$ . The exponential dependence in this bound is necessary: there exist graphs whose clique-width is exponentially larger than their treewidth.^[10] In the other direction, graphs of bounded clique-width can have unbounded treewidth; for instance, $n$ -vertex complete graphs have clique-width 2 but treewidth $n - 1$ . However, graphs of clique-width $k$ that have no complete bipartite graph $K t, t$ as a subgraph have treewidth at most $3 k (t - 1) - 1$ . Therefore, for every family of sparse graphs, having bounded treewidth is equivalent to having bounded clique-width.^[11]
Another graph parameter, the rank-width, is bounded in both directions by the clique-width: rank-width ≤ clique-width ≤ 2^{rank-width + 1}.^[12]

Additionally, if a graph $G$ has clique-width $k$ , then the graph power $G c$ has clique-width at most $2 kc k$ .^[13] Although there is an exponential gap in both the bound for clique-width from treewidth and the bound for clique-width of graph powers, these bounds do not compound each other: if a graph $G$ has treewidth $w$ , then $G c$ has clique-width at most $2(c + 1) w + 1 - 2$ , only singly exponential in the treewidth.^[14]

Computational complexity

Unsolved problem in mathematics:

Can graphs of bounded clique-width be recognized in polynomial time?
(more unsolved problems in mathematics)

Many optimization problems that are NP-hard for more general classes of graphs may be solved efficiently by dynamic programming on graphs of bounded clique-width, when a construction sequence for these graphs is known.^[15]^[16] In particular, every graph property that can be expressed in MSO₁ monadic second-order logic (a form of logic allowing quantification over sets of vertices) has a linear-time algorithm for graphs of bounded clique-width, by a form of Courcelle's theorem.^[16] It is also possible to find optimal graph colorings or Hamiltonian cycles for graphs of bounded clique-width in polynomial time, when a construction sequence is known, but the exponent of the polynomial increases with the clique-width, and evidence from computational complexity theory shows that this dependence is likely to be necessary.^[17]

The graphs of clique-width three can be recognized, and a construction sequence found for them, in polynomial time using an algorithm based on split decomposition.^[18] For graphs of unbounded clique-width, it is NP-hard to compute the clique-width exactly, and also NP-hard to obtain an approximation with sublinear additive error.^[19] However, when the clique-width is bounded, it is possible to obtain a construction sequence of bounded width (exponentially larger than the actual clique-width) in polynomial time.^[20] It remains open whether the exact clique-width, or a tighter approximation to it, can be calculated in fixed-parameter tractable time, whether it can be calculated in polynomial time for every fixed bound on the clique-width, or even whether the graphs of clique-width four can be recognized in polynomial time.^[19]

Relation to treewidth

The theory of graphs of bounded clique-width resembles that for graphs of bounded treewidth, but unlike treewidth allows for dense graphs. If a family of graphs has bounded clique-width, then either it has bounded treewidth or every complete bipartite graph is a subgraph of a graph in the family.^[11] Treewidth and clique-width are also connected through the theory of line graphs: a family of graphs has bounded treewidth if and only if their line graphs have bounded clique-width.^[21]

Notes

References

Brandstädt, A.; Dragan, F.F.; Le, H.-O.; Mosca, R. (2005), "New graph classes of bounded clique-width", Theory of Computing Systems, 38: 623–645, doi:10.1007/s00224-004-1154-6 .
Brandstädt, A.; Engelfriet, J.; Le, H.-O.; Lozin, V.V. (2006), "Clique-width for 4-vertex forbidden subgraphs", Theory of Computing Systems, 39: 561–590, doi:10.1007/s00224-005-1199-1 .
Brandstädt, Andreas; Hundt, Christian (2008), "Ptolemaic graphs and interval graphs are leaf powers", LATIN 2008: Theoretical informatics, Lecture Notes in Comput. Sci., 4957, Springer, Berlin, pp. 479–491, doi:10.1007/978-3-540-78773-0_42, MR 2472761 .
Brandstädt, A.; Lozin, V.V. (2003), "On the linear structure and clique-width of bipartite permutation graphs", Ars Combinatoria, 67: 273–281 .
Chlebíková, J. (1992), "On the tree-width of a graph", Acta Mathematica Universitatis Comenianae, New Series, 61 (2): 225–236, MR 1205875 .
Cogis, O.; Thierry, E. (2005), "Computing maximum stable sets for distance-hereditary graphs", Discrete Optimization, 2 (2): 185–188, doi:10.1016/j.disopt.2005.03.004, MR 2155518 .
Corneil, Derek G.; Habib, Michel; Lanlignel, Jean-Marc; Reed, Bruce; Rotics, Udi (2012), "Polynomial-time recognition of clique-width $\leq 3$ graphs", Discrete Applied Mathematics, 160 (6): 834–865, doi:10.1016/j.dam.2011.03.020, MR 2901093 .
Corneil, Derek G.; Rotics, Udi (2005), "On the relationship between clique-width and treewidth", SIAM Journal on Computing, 34 (4): 825–847, doi:10.1137/S0097539701385351, MR 2148860 .
Courcelle, Bruno; Engelfriet, Joost; Rozenberg, Grzegorz (1993), "Handle-rewriting hypergraph grammars", Journal of Computer and System Sciences, 46 (2): 218–270, doi:10.1016/0022-0000(93)90004-G, MR 1217156 . Presented in preliminary form in Graph grammars and their application to computer science (Bremen, 1990), MR 1431281.
Courcelle, B. (1993), "Monadic second-order logic and hypergraph orientation", Proceedings of Eighth Annual IEEE Symposium on Logic in Computer Science (LICS '93), pp. 179–190, doi:10.1109/LICS.1993.287589 .
Courcelle, B.; Makowsky, J. A.; Rotics, U. (2000), "Linear time solvable optimization problems on graphs on bounded clique width", Theory of Computing Systems, 33 (2): 125–150, doi:10.1007/s002249910009 .
Courcelle, B.; Olariu, S. (2000), "Upper bounds to the clique width of graphs", Discrete Applied Mathematics, 101 (1–3): 77–144, doi:10.1016/S0166-218X(99)00184-5 .
Fellows, Michael R.; Rosamond, Frances A.; Rotics, Udi; Szeider, Stefan (2009), "Clique-width is NP-complete", SIAM Journal on Discrete Mathematics, 23 (2): 909–939, doi:10.1137/070687256, MR 2519936 .
Fomin, Fedor V.; Golovach, Petr A.; Lokshtanov, Daniel; Saurabh, Saket (2010), "Intractability of clique-width parameterizations", SIAM Journal on Computing, 39 (5): 1941–1956, doi:10.1137/080742270, MR 2592039 .
Golumbic, Martin Charles; Rotics, Udi (2000), "On the clique-width of some perfect graph classes", International Journal of Foundations of Computer Science, 11 (3): 423–443, doi:10.1142/S0129054100000260, MR 1792124 .
Gurski, Frank; Wanke, Egon (2000), "The tree-width of clique-width bounded graphs without $K n,n$ ", in Brandes, Ulrik; Wagner, Dorothea, Graph-Theoretic Concepts in Computer Science: 26th International Workshop, WG 2000, Konstanz, Germany, June 15–17, 2000, Proceedings, Lecture Notes in Computer Science, 1928, Berlin: Springer, pp. 196–205, doi:10.1007/3-540-40064-8_19, MR 1850348 .
Gurski, Frank; Wanke, Egon (2007), "Line graphs of bounded clique-width", Discrete Mathematics, 307 (22): 2734–2754, doi:10.1016/j.disc.2007.01.020 .
Gurski, Frank; Wanke, Egon (2009), "The NLC-width and clique-width for powers of graphs of bounded tree-width", Discrete Applied Mathematics, 157 (4): 583–595, doi:10.1016/j.dam.2008.08.031, MR 2499471 .
Hliněný, Petr; Oum, Sang-il (2008), "Finding branch-decompositions and rank-decompositions", SIAM Journal on Computing, 38 (3): 1012–1032, doi:10.1137/070685920, MR 2421076 .
Oum, Sang-il; Seymour, Paul (2006), "Approximating clique-width and branch-width", Journal of Combinatorial Theory, Series B, 96 (4): 514–528, doi:10.1016/j.jctb.2005.10.006, MR 2232389 .
Oum, Sang-il (2009), "Approximating rank-width and clique-width quickly", ACM Transactions on Algorithms, 5 (1): Art. 10, 20, doi:10.1007/11604686_5, MR 2479181 .
Todinca, Ioan (2003), "Coloring powers of graphs of bounded clique-width", Graph-theoretic concepts in computer science, Lecture Notes in Comput. Sci., 2880, Springer, Berlin, pp. 370–382, doi:10.1007/978-3-540-39890-5_32, MR 2080095 .
Wanke, Egon (1994), " $k$ -NLC graphs and polynomial algorithms", Discrete Applied Mathematics, 54 (2-3): 251–266, doi:10.1016/0166-218X(94)90026-4, MR 1300250 .

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