Word-representable graph: Difference between revisions

The word ''w'' is ''G''<nowiki/>'s ''word-representant'', and one says that that ''w'' ''represents'' ''G''. The smallest (by the number of&nbsp; vertices) non-word-representable graph is the [[wheel graph]] ''W''₅, which is the only non-word-representable graph on 6 vertices.

The definition of a word-representable graph works both in labelled and unlabelled cases since any labelling of a graph is equivalent to any other labelling. Also, the class of word-representable graphs is [[Hereditary property|hereditary]]. Word-representable graphs generalise several important classes of graphs such as [[Circlecircle graph|circle graphs]]s, [[Graph coloring|3-colorable graphs]] and [[Comparabilitycomparability graph|comparability graphs]]s. Various generalisations of the theory of word-representable graphs accommodate representation of ''any'' graph.

Word-representable graphs were introduced by [[Sergey Kitaev]]<ref>{{cite journal |last=Steingrímsson |first=Einar |author-link=Einar Steingrímsson|title=The history of the Gothenburg–Reykjavík–Strathclyde Combinatorics Group |journal=Enumerative Combinatorics and Applications |date=2023 |volume=3 |issue=1|pages=Article S1H1 |doi=10.54550/ECA2023V3S1H1|url=http://ecajournal.haifa.ac.il/Volume2023/ECA2023_S1H1.pdf}}</ref> in 2004 based on joint research with Steven Seif<ref name="KS08">S. Kitaev and S. Seif. Word problem of the Perkins semigroup via directed acyclic graphs, Order 25 (2008), 177−194.</ref> on the ''[[Perkins semigroup]]'', which has played an important role in semigroup theory since 1960.<ref name="KL15">[https://www.springer.com/la/book/9783319258577 S. Kitaev and V. Lozin. Words and Graphs, Springer, 2015.] {{ISBN|978-3-319-25859-1}}</ref> The first systematic study of word-representable graphs was undertaken in a 2008 paper by Kitaev and Artem Pyatkin,<ref name="KP08">[https://personal.cis.strath.ac.uk/sergey.kitaev/index_files/Papers/repgr.pdf S. Kitaev and A. Pyatkin. On representable graphs, J. Autom., Lang. and Combin. 13 (2008), 45−54.]</ref> starting development of the theory. One of key contributors to the area is [http://www.ru.is/~mmh/ Magnús M. Halldórsson].<ref name=":0">[https://link.springer.com/chapter/10.1007/978-3-642-14455-4_41 M.M. Halldórsson, S. Kitaev, A. Pyatkin (2010) Graphs capturing alternations in words. In: Y. Gao, H. Lu, S. Seki, S. Yu (eds), Developments in Language Theory. DLT 2010. Lecture Notes Comp. Sci. 6224, Springer, 436−437.]</ref><ref name=":1">[https://link.springer.com/chapter/10.1007/978-3-642-25870-1_18 M.M. Halldórsson, S. Kitaev, A. Pyatkin (2011) Alternation graphs. In: P. Kolman, J. Kratochvíl (eds), Graph-Theoretic Concepts in Computer Science. WG 2011. Lecture Notes Comp. Sci. 6986, Springer, 191−202.]</ref><ref name="HKP16">[https://www.sciencedirect.com/science/article/pii/S0166218X15003868 M. Halldórsson, S. Kitaev and A. Pyatkin. Semi-transitive orientations and word-representable graphs, Discr. Appl. Math. 201 (2016), 164−171.]</ref>. Up to date, 35+ papers have been written on the subject, and the core of the book<ref name="KL15" /> by Sergey Kitaev and Vadim Lozin is devoted to the theory of word-representable graphs. A quick way to get familiar with the area is to read one of the survey articles.<ref name=":2">[[arxiv:1705.05924|S. Kitaev. A comprehensive introduction to the theory of word-representable graphs.]] In: É. Charlier, J. Leroy, M. Rigo (eds), Developments in Language Theory. DLT 2017. Lecture Notes Comp. Sci. 10396, Springer, 36−67.</ref><ref name=":3">[https://link.springer.com/article/10.1134/S1990478918020084 S. Kitaev and A. Pyatkin. Word-representable graphs: a Survey, Journal of Applied and Industrial Mathematics 12(2) (2018) 278−296.]</ref><ref name=":4">[http://www.mathnet.ru/php/archive.phtml?wshow=paper&jrnid=da&paperid=894&option_lang=rus С. В. Китаев, А. В. Пяткин. Графы, представимые в виде слов. Обзор результатов, Дискретн. анализ и исслед. опер., 2018, том 25,номер 2, 19−53]</ref>.

It was shown in <ref name="KP08" /> that a graph ''G'' is word-representable iffif it is '''k-representable''' for some ''k'', that is, ''G'' can be represented by a word having ''k'' copies of each letter. Moreover, if a graph is ''k''-representable then it is also (''k''&nbsp;+&nbsp;1)-representable. Thus, the notion of the '''representation number of a graph''', as the ''minimum'' ''k'' such that a graph is word-representable, is well-defined. Non-word-representable graphs have the representation number ∞. Graphs with representation number 1 are precisely the set of [[Completecomplete graph|complete graphs]]s, while graphs with representation number 2 are precisely the class of [[Circle graph|circle]] non-complete graphs. In particular, [http://mathworld.wolfram.com/Forest.html forests] (except for single [[Tree (graph theory)|trees]] on at most 2 vertices), [[Ladderladder graph|ladder graphs]]s and [[Cyclecycle graph|cycle graphs]]s have representation number 2. No classification for graphs with representation number 3 is known. However, there are examples of such graphs, e.g. [[Petersen graph|Petersen's graph]] and [http://mathworld.wolfram.com/PrismGraph.html prisms]. Moreover, the 3-[[Homeomorphism (graph theory)|subdivision]] of any graph is 3-representable. In particular, for every graph ''G'' there exists a 3-representable graph ''H'' that contains ''G'' as a [[Graph minor|minor]] .<ref name="KP08" />.

A graph ''G'' is '''permutationally representable''' if it can be represented by a word of the form ''p''₁''p''₂...''p_k'', where ''p_i'' is a [[permutation]]. On can also say that ''G'' is '''permutationally ''k''-representable'''. A graph is permutationally representable iff it is a [[Comparability graph|comparability graph]] .<ref name="KS08" />. A graph is word-representable implies that the [[Neighbourhood (graph theory)|neighbourhood]] of each vertex is permutationally representable (i.e. is a [[comparability graph]]) .<ref name="KS08" />. Converse to the last statement is not true .<ref name=":0" />. However, the fact that the [[Neighbourhood (graph theory)|neighbourhood]] of each vertex is a [[comparability graph]] implies that the [[Clique problem|Maximum Clique problem]] is polynomially solvable on word-representable graphs .<ref name=":1" /> <ref name="HKP16" />.

Semi-transitive orientations provide a powerful tool to study word-representable graphs. A directed graph is '''semi-transitively oriented''' iff it is [http://mathworld.wolfram.com/AcyclicGraph.html acyclic] and for any directed path ''u''₁→''u''₂→ ...→''u_t'', ''t'' ≥ 2, either there is no edge from ''u''₁ to ''u_t'' or all edges ''u_i'' → ''u_j'' exist for 1 ≤ ''i'' < ''j'' ≤ ''t''. A key theorem in the theory of word-representable graphs states that a graph is word-representable iff it admits a semi-transitive orientation .<ref name="HKP16" />. As a corollary to the proof of the key theorem one obtain an upper bound on word-representants: Each non-complete word-representable graph ''G'' is 2(''n''&nbsp;−&nbsp;''κ''(''G''))-representable, where ''κ''(''G'') is the size of a maximal clique in ''G'' .<ref name="HKP16" />. As an immediate corollary of the last statement, one has that the [https://www.encyclopediaofmath.org/index.php/Recognition_problem recognition problem] of word-representability is in [[NP (complexity)|NP]]. In 2014, [http://fc.isima.fr/~limouzy/ Vincent Limouzy] observed that it is an [[NP-completeness|NP-complete problem]] to recognise whether a given graph is word-representable .<ref name="KL15" /> <ref name=":2" />. Another important corollary to the key theorem is that any [[Graph coloring|3-colorable graph]] is word-representable. The last fact implies that many classical graph problems are NP-hard on word-representable graphs.  

[[Wheel graph|Wheel graphs]]s ''W''_2''n''+1, for ''n'' ≥ 2, are not word-representable and ''W''₅ is the minimum (by the number of vertices) non-word-representable graph. Taking any non-comparability graph and adding an apex (a vertex connected to any other vertex), we obtain a non-word-representable graph, which then can produce infinitely many non-word-representable graphs .<ref name="KL15" />. Any graph produced in this way will necessarily have a triangle (a cycle of length 3), and a vertex of degree at least 5. Non-word-representable graphs of maximum degree 4 exist <ref>[[arxiv:1307.1810|A. Collins, S. Kitaev, and V. Lozin. New results on word-representable graphs, Discr. Appl. Math. 216 (2017), 136–141.]]</ref> and non-word-representable triangle-free graphs exist .<ref name=":1" />. Regular non-word representable graphs also exist .<ref name="KL15" />. Non-isomorphic non-word-representable connected graphs on at most eight vertices were first enumerated by Heman Z.Q. Chen. His calculations were extended in ,<ref>[https://cs.uwaterloo.ca/journals/JIS/VOL22/Kitaev/kitaev11.html Ö. Akgün, I.P. Gent, S. Kitaev, H. Zantema. Solving computational problems in the theory of word-representable graphs. Journal of Integer Sequences 22 (2019), Article 19.2.5.]

</ref>, where it was shown that the numbers of non-isomorphic non-word-representable connected graphs on 5−11 vertices are given, respectively, by 0, 1, 25, 929, 54957, 4880093, 650856040. This is the sequence A290814 in the [http://oeis.org/search?q=1%2C+25%2C+929%2C+54957%2C+4880093&language=english&go=Search Online Encyclopaedia of Integer Sequences (OEIS)].

Operations preserving word-representability are removing a vertex, replacing a vertex with a module, Cartesian product, rooted product, subdivision of a graph, connecting two graphs by an edge and gluing two graphs in a vertex .<ref name="KL15" />. The operations not necessarily preserving word-representability are taking the complement, taking the line graph, edge contraction ,<ref name="KL15" />, gluing two graphs in a clique of size 2 or more ,<ref name="CKS2019" />, tensor product, lexicographic product and strong product .<ref name="CKK2019">[https://link.springer.com/content/pdf/10.1007/s10878-018-0358-7.pdf I. Choi, J. Kim, and M. Kim. On operations preserving semi-transitive orient ability of graphs, Journal of Combinatorial Optimization 37 (2019) 4, 1351−1366.]</ref>. Edge-deletion, edge-addition and edge-lifting with respect to word-representability (equivalently, semi-transitive orientability) are studied in .<ref name="CKK2019" />.

While each non-complete word-representable graph ''G'' is 2(''n''&nbsp;−&nbsp;''κ''(''G''))-representable, where ''κ''(''G'') is the size of a maximal clique in ''G'' ,<ref name="HKP16" />, the highest known representation number is floor(''n''/2) given by [[Crowncrown graph|crown graphs]]s with an all-adjacent vertex .<ref name="HKP16" />. Interestingly, such graphs are not the only graphs that require long representations .<ref name="AGKZ2019">[https://cs.uwaterloo.ca/journals/JIS/VOL22/Kitaev/kitaev11.pdf Ö. Akgün, I.P. Gent, S. Kitaev, H. Zantema. Solving computational problems in the theory of word-representable graphs. Journal of Integer Sequences 22 (2019), Article 19.2.5.]</ref>. Crown graphs themselves are shown to require long (possibly longest) representations among bipartite graphs .<ref name="GKP18">[https://www.sciencedirect.com/science/article/pii/S0166218X18301045 M. Glen, S. Kitaev, and A. Pyatkin. On the representation number of a crown graph, Discr. Appl. Math. 244, 2018, 89–93.]</ref>.

Known computational complexities for problems on word-representable graphs can be summarised as follows :<ref name="KL15" /> <ref name=":2" />:

Triangle-free [[planar graphs]] are word-representable .<ref name="HKP16" />. A K4-free near-triangulation is 3-colourable if and only if it is word-representable ;<ref name="Glen2019">[[arxiv:1605.01688|M. Glen. Colourability and word-representability of near-triangulations, Pure and Applied Mathematics, to appear, 2019.]]</ref>; this result generalises studies in .<ref name="AKM2015">[[arxiv:1405.3527|P. Akrobotu, S. Kitaev, and Z. Masárová. On word-representability of polyomino triangulations. Siberian Adv. Math. 25 (2015), 1−10.]]</ref><ref name="GK2017">[[arxiv:1503.05076|M. Glen and S. Kitaev. Word-Representability of Triangulations of Rectangular Polyomino with a Single Domino Tile, J. Combin.Math. Combin. Comput. 100, 131−144, 2017.]]</ref>. Word-representability of face subdivisions of triangular grid graphs is studied in <ref name="CKS2016">[[arxiv:1503.08002|T. Z. Q. Chen, S. Kitaev, and B. Y. Sun. Word-representability of face subdivisions of triangular grid graphs, Graphs and Combin. 32(5) (2016), 1749−1761.]]</ref> and word-representability of triangulations of grid-covered cylinder graphs is studied in .<ref name="CKS2016-2">[[arxiv:1507.06749|T. Z. Q. Chen, S. Kitaev, and B. Y. Sun. Word-representability of triangulations of grid-covered cylinder graphs, Discr. Appl. Math. 213 (2016), 60−70.]]</ref>.

Word-representation of [[Splitsplit graph|split graphs]]s is studied in .<ref name="KLMW2017">[[arxiv:1709.09725|S. Kitaev, Y. Long, J. Ma, H. Wu. Word-representability of split graphs, arXiv:1709.09725 (2017).]]</ref><ref name="CKS2019">[[arXiv:1909.09471|T. Z. Q. Chen, S. Kitaev, and A. Saito. Representing split graphs by words, arXiv:1909.09471]]</ref>. In particular, <ref name="KLMW2017" /> offers a characterisation in terms of forbidden induced subgraphs of word-representable split graphs in which vertices in the independent set are of degree at most 2, or the size of the clique is 4, while a computational characterisation of word-representable split graphs with the clique of size 5 is given in .<ref name="CKS2019" />. Also, necessary and sufficient conditions for an orientation of a split graph to be semi-transitive are given in ,<ref name="KLMW2017" />, while in <ref name="CKS2019" /> [[Thresholdthreshold graph|threshold graphs]]s are shown to be word-representable and the split graphs are used to show that gluing two word-representable graphs in any clique of size at least 2 may, or may not result in a word-representable graph, which solved a long-standing open problem.

A graph is '''''p''-representable''' if it can be represented by a word avoiding a [[Permutation pattern|pattern]] ''p''. For example, 132-representable graphs are those that can be represented by words ''w''₁w₂...''w_n'' where there are no 1 ≤ ''a'' < ''b'' < ''c'' ≤ ''n'' such that ''w_a'' < ''w_c'' < ''w_b''. In <ref name="GKZ2017">[[arxiv:1602.08965|A. Gao, S. Kitaev, and P. Zhang. On 132-representable graphs. Australasian J. Combin. 69 (2017), 105−118.]]</ref> it is shown that any 132-representable graph is necessarily a [[circle graph]], and any [[Tree (graph theory)|tree]] and any [[cycle graph]], as well as any graph on at most 5 vertices, are 132-representable. It was shown in <ref name="M2019">[https://www.dmgt.uz.zgora.pl/publish/view_pdf.php?ID=-2009|Y. Mandelshtam. On graphs representable by pattern-avoiding words, Discussiones Mathematicae Graph Theory 39 (2019) 375−389.]</ref> that not all circle graphs are 132-representable, and that 123-representable graphs are also a proper subclass of the class of circle graphs.

A number of generalisations <ref name="JKPR2015">[https://www.combinatorics.org/ojs/index.php/eljc/article/view/v22i2p53 M. Jones, S. Kitaev, A. Pyatkin, and J. Remmel. Representing Graphs via Pattern Avoiding Words, Electron. J. Combin. 22 (2), Res. Pap. P2.53, 1−20 (2015).]</ref><ref name="GJ2019">[https://www.lehmanns.de/shop/mathematik-informatik/48968161-9783030287955-combinatorics-on-words M. Gaetz and C. Ji. Enumeration and extensions of word-representable graphs. Lecture Notes in Computer Science 11682 (2019) 180−192. In R. Mercas, D. Reidenbach (Eds) Combinatorics on Words. WORDS 2019.]</ref><ref name="GJ2019-2">[[arXiv:1909.00019|M. Gaetz and C. Ji. Enumeration and Extensions of Word-representants, arXiv:1909.00019.]]</ref> of the notion of a word-representable graph are based on the observation by [https://www[Jeffrey B.math.ucsd.edu/memorials/jeffrey-remmel/ Remmel|Jeff Remmel]] that non-edges are defined by occurrences of the pattern 11 (two consecutive equal letters) in a word representing a graph, while edges are defined by avoidance of this pattern. For example, instead of the pattern 11, one can use the pattern 112, or the pattern, 1212, or any other binary pattern where the assumption that the alphabet is ordered can be made so that a letter in a word corresponding to 1 in the pattern is less than that corresponding to 2 in the pattern. Letting ''u'' be an ordered binary pattern we thus get the notion of a '''''u''-representable graph'''. So, word-representable graphs are just the class of 11-representable graphs. Intriguingly, '''any graph''' can be ''u''-represented assuming ''u'' is of length at least 3 .<ref name="K2017">[https://onlinelibrary.wiley.com/doi/full/10.1002/jgt.22097 S. Kitaev. Existence of u-representation of graphs, Journal of Graph Theory 85 (2017) 3, 661−668.]</ref>.

The list of publications to study representation of graphs by words contains, but is not limited to

# [https://web.archive.org/web/20190302114930/http://pdfs.semanticscholar.org/a2df/a4c88505510ea1a7d4357972d9ab24575195.pdf M.M. Halldórsson, S. Kitaev, A. Pyatkin (2010) Graphs capturing alternations in words. In: Y. Gao, H. Lu, S. Seki, S. Yu (eds), Developments in Language Theory. DLT 2010. Lecture Notes Comp. Sci. 6224, Springer, 436−437.]

#[http://personal.strath.ac.uk/sergey.kitaev/word-representable-graphs.html M. E. Glen. Software to deal with word-representable graphs, 2017. Available at https://personal.cis.strath.ac.uk/sergey.kitaev/word-representable-graphs.html.]