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that visits each vertex exactly once. A Hamiltonian path that starts and ends at adjacent vertices can be completed by adding one more edge to form a
Hamiltonian cycle, and removing any edge from a Hamiltonian cycle produces a Hamiltonian path. The computational problems of determining whether such
935:
of its weighted adjacency matrix defined as the sum of the products of the arc weights of the digraph's
Hamiltonian cycles. This polynomial is not identically zero as a function in the arc weights if and only if the digraph is Hamiltonian. The relationship between the computational complexities of
859:
The number of vertices must be doubled because each undirected edge corresponds to two directed arcs and thus the degree of a vertex in the directed graph is twice the degree in the undirected graph.
404:
Any
Hamiltonian cycle can be converted to a Hamiltonian path by removing one of its edges, but a Hamiltonian path can be extended to a Hamiltonian cycle only if its endpoints are adjacent.
293:
447:, so the line graph of every Eulerian graph is Hamiltonian. Line graphs may have other Hamiltonian cycles that do not correspond to Euler tours, and in particular the line graph
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240:, where each edge (arc) of a path or cycle can only be traced in a single direction (i.e., the vertices are connected with arrows and the edges traced "tail-to-head").
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687:
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854:
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As complete graphs are
Hamiltonian, all graphs whose closure is complete are Hamiltonian, which is the content of the following earlier theorems by Dirac and Ore.
896:, in which the vertex degrees are compared to the number of vertices on a single side of the bipartition rather than the number of vertices in the whole graph.
286:
1620:
1066:
931:
An algebraic representation of the
Hamiltonian cycles of a given weighted digraph (whose arcs are assigned weights from a certain ground field) is the
1222:
Gardner, M. "Mathematical Games: About the
Remarkable Similarity between the Icosian Game and the Towers of Hanoi." Sci. Amer. 196, 150–156, May 1957
279:
881:
vertices has a
Hamiltonian path if, for every non-adjacent vertex pairs the sum of their degrees and their shortest path length is greater than
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30:
This article is about the nature of
Hamiltonian paths. For the question of the existence of a Hamiltonian path or cycle in a given graph, see
1875:
1160:
1845:
1579:
1363:
140:, who, in particular, gave an example of a polyhedron without Hamiltonian cycles. Even earlier, Hamiltonian cycles and paths in the
1309:
1880:
1725:
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vertices is
Hamiltonian if the sum of full degrees of every pair of distinct non-adjacent vertices is greater than or equal to
1045:
1233:
Ghaderpour, E.; Morris, D. W. (2014). "Cayley graphs on nilpotent groups with cyclic commutator subgroup are
Hamiltonian".
1200:
1870:
1865:
1796:
1444:
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161:
932:
474:
1095:
1562:
Kogan, Grigoriy (1996). "Computing permanents over fields of characteristic 3: Where and why it becomes difficult".
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559:
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The above theorem can only recognize the existence of a Hamiltonian path in a graph and not a Hamiltonian Cycle.
518:. These counts assume that cycles that are the same apart from their starting point are not counted separately.
470:
429:
in which every vertex has even degree) necessarily has an Euler tour, a closed walk passing through each edge of
321:
244:
992:
814:
785:
95:
31:
950:
1723:
Meyniel, M. (1973), "Une condition suffisante d'existence d'un circuit hamiltonien dans un graphe orienté",
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563:
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Despite being named after Hamilton, Hamiltonian cycles in polyhedra had also been studied a year earlier by
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17:
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that visits each vertex of the graph exactly once. A graph that contains a Hamiltonian path is called a
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among other parameters. Dirac and Ore's theorems basically state that a graph is Hamiltonian if it has
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is a type of logic puzzle in which the goal is to find the unique Hamiltonian cycle in a given graph.
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550:(1962). Hamiltonicity has been widely studied with relation to various parameters such as graph
1828:
1575:
1359:
1353:
1307:; Noy, Marc (1999), "Graph of triangulations of a convex polygon and tree of triangulations",
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that visits each vertex exactly once. A graph that contains a Hamiltonian cycle is called a
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766:) is Hamiltonian if, for every pair of non-adjacent vertices, the sum of their degrees is
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165:
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Rahman, M. S.; Kaykobad, M. (April 2005). "On Hamiltonian cycles and Hamiltonian paths".
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is Hamiltonian (For more information on Hamiltonian paths in Cayley graphs, see the
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133:(also invented by Hamilton). This solution does not generalize to arbitrary graphs.
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if for every pair of vertices there is a Hamiltonian path between the two vertices.
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vertices is Hamiltonian if every vertex has a full degree greater than or equal to
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1053:, a numerical measure of how far from Hamiltonian the graphs in a family can be
1001:, a non-Hamiltonian graph in which every vertex-deleted subgraph is Hamiltonian
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of the vertices of the five platonic solids – only the octahedron has an
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434:
368:
145:
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The number of different Hamiltonian cycles in a complete undirected graph on
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that does not have a Hamiltonian cycle. A possible Hamiltonian path is shown.
1836:
1439:
1278:
Lucas, Joan M. (1987), "The rotation graph of binary trees is Hamiltonian",
977:
1129:
411:, but a biconnected graph need not be Hamiltonian (see, for example, the
37:
1780:
1510:
1457:
157:
113:, which involves finding a Hamiltonian cycle in the edge graph of the
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1502:
1042:, a strengthening of both pancyclicity and Hamiltonian-connectedness
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characterization of Hamiltonian graphs was provided in 1972 by the
1247:
641:
A graph is Hamiltonian if and only if its closure is Hamiltonian.
473:(with more than two vertices) is Hamiltonian if and only if it is
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exactly once. This tour corresponds to a Hamiltonian cycle in the
387:
261:
44:
36:
1564:
Proceedings of 37th Conference on Foundations of Computer Science
1036:, graphs with cycles of all lengths including a Hamiltonian cycle
1688:(1856), "Memorandum respecting a new system of roots of unity",
247:
is an edge decomposition of a graph into Hamiltonian circuits.
1352:
Balakrishnan, R.; Ranganathan, K. (2012), "Corollary 6.5.5",
774:
The following theorems can be regarded as directed versions:
911:
A 4-connected planar triangulation has a Hamiltonian cycle.
546:. Both Dirac's and Ore's theorems can also be derived from
168:. In 18th century Europe, knight's tours were published by
1621:"A study of sufficient conditions for Hamiltonian cycles"
49:
Examples of Hamiltonian cycles on a square grid graph 8x8
1153:
Across the Board: The Mathematics of Chessboard Problems
995:, the computational problem of finding Hamiltonian paths
462:
is itself Hamiltonian, regardless of whether the graph
1151:
Watkins, John J. (2004), "Chapter 2: Knight's Tours",
697:
1116:
Biggs, N. L. (1981), "T. P. Kirkman, mathematician",
833:
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until no more pairs with this property can be found.
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A 4-connected planar graph has a Hamiltonian cycle.
274:
or cycle, by extending its path with the dotted one
266:
Orthographic projections and Schlegel diagrams with
73:
in an undirected or directed graph that visits each
41:
A Hamiltonian cycle around a network of six vertices
27:
Path in a graph that visits each vertex exactly once
594:vertices, obtained by repeatedly adding a new edge
892:Many of these results have analogues for balanced
848:
758:
710:
681:
1381:"Advances on the Hamiltonian Problem – A Survey"
900:Existence of Hamiltonian cycles in planar graphs
1799:(1962), "A theorem concerning Hamilton lines",
1118:The Bulletin of the London Mathematical Society
1658:Proceedings of the London Mathematical Society
1612:Programming, games and transportation networks
1155:, Princeton University Press, pp. 25–38,
538:theorem, which generalizes earlier results by
287:
101:Hamiltonian paths and cycles are named after
8:
1656:(1952), "Some theorems on abstract graphs",
953:, an open problem on Hamiltonicity of cubic
689:) is Hamiltonian if every vertex has degree
1707:(1858), "Account of the Icosian Calculus",
1442:(1963), "On Hamiltonian bipartite graphs",
916:
905:
863:
807:
778:
723:
649:
635:
573:The Bondy–Chvátal theorem operates on the
310:with more than two vertices is Hamiltonian
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280:
117:. Hamilton solved this problem using the
18:Dirac's theorem on Hamiltonian cycles
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371:of a convex polygon or equivalently, the
152:, had been studied in the 9th century in
1801:Magyar Tud. Akad. Mat. Kutató Int. Közl.
324:has an odd number of Hamiltonian paths (
1108:
335:, considered as a graph, is Hamiltonian
1861:Computational problems in graph theory
1710:Proceedings of the Royal Irish Academy
1628:Rose-Hulman Undergraduate Math Journal
1534:(1956), "A theorem on planar graphs",
1759:(1960), "Note on Hamilton circuits",
1178:Hamilton Mazes – The Beginner's Guide
965:, a path through all edges in a graph
90:paths and cycles exist in graphs are
7:
1069:for finding a Hamiltonian path in a
506:and in a complete directed graph on
1067:Steinhaus–Johnson–Trotter algorithm
234:Similar notions may be defined for
1386:. Emory University. Archived from
1203:from the original on 16 April 2016
25:
1761:The American Mathematical Monthly
1549:10.1090/s0002-9947-1956-0081471-8
1379:Gould, Ronald J. (July 8, 2002).
1088:(now known false) that 3-regular
985:giving a necessary condition for
927:The Hamiltonian cycle polynomial
1726:Journal of Combinatorial Theory
1489:(1931), "A theorem on graphs",
711:{\displaystyle {\tfrac {n}{2}}}
1846:Euler tour and Hamilton cycles
1413:Information Processing Letters
160:, and around the same time in
129:with many similarities to the
1:
1610:; Ghouila-Houiri, A. (1962),
1445:Israel Journal of Mathematics
1324:10.1016/S0925-7721(99)00016-4
1235:Ars Mathematica Contemporanea
1007:, a Hamiltonian cycle in the
940:was shown by Grigoriy Kogan.
1876:Hamiltonian paths and cycles
1740:10.1016/0095-8956(73)90057-9
1292:10.1016/0196-6774(87)90048-4
933:Hamiltonian cycle polynomial
636:Bondy–Chvátal Theorem (1976)
1096:Travelling salesman problem
1046:Seven Bridges of Königsberg
989:to have a Hamiltonian cycle
458:of every Hamiltonian graph
407:All Hamiltonian graphs are
1897:
1355:A Textbook of Graph Theory
1257:10.26493/1855-3974.280.8d3
29:
1425:10.1016/j.ipl.2004.12.002
1358:, Springer, p. 134,
1176:de Ruiter, Johan (2017).
396:is the smallest possible
245:Hamiltonian decomposition
1619:DeLeon, Melissa (2000),
1572:10.1109/SFCS.1996.548469
1191:Friedman, Erich (2009).
1028:vertex-transitive graphs
993:Hamiltonian path problem
96:Hamiltonian path problem
32:Hamiltonian path problem
1705:Hamilton, William Rowan
1686:Hamilton, William Rowan
1536:Trans. Amer. Math. Soc.
938:computing the permanent
759:{\displaystyle n\geq 3}
682:{\displaystyle n\geq 3}
1881:William Rowan Hamilton
1691:Philosophical Magazine
1670:10.1112/plms/s3-2.1.69
1614:, New York: Sons, Inc.
1310:Computational Geometry
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683:
650:Dirac's Theorem (1952)
401:
302:
103:William Rowan Hamilton
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1491:Annals of Mathematics
1280:Journal of Algorithms
1197:Erich's Puzzle Palace
999:Hypohamiltonian graph
951:Barnette's conjecture
851:
779:Ghouila–Houiri (1960)
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713:
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522:Bondy–Chvátal theorem
391:
265:
202:Hamiltonian-connected
48:
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1871:Graph theory objects
1866:NP-complete problems
1566:. pp. 108–114.
1341:. Wolfram MathWorld.
1130:10.1112/blms/13.2.97
1076:Subhamiltonian graph
969:Fleischner's theorem
849:{\displaystyle 2n-1}
831:
744:
693:
667:
109:, now also known as
1832:"Hamiltonian Cycle"
1634:(1), archived from
1339:"Biconnected Graph"
1193:"Hamiltonian Mazes"
920: —
909: —
871: —
811: —
782: —
730: —
653: —
639: —
560:forbidden subgraphs
362:commutator subgroup
213:Hamiltonian circuit
162:Islamic mathematics
123:algebraic structure
105:, who invented the
83:Hamiltonian circuit
1829:Weisstein, Eric W.
1458:10.1007/BF02759704
1078:, a subgraph of a
1051:Shortness exponent
983:Grinberg's theorem
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815:strongly connected
809:
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475:strongly connected
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268:Hamiltonian cycles
154:Indian mathematics
51:
43:
1493:, Second Series,
1162:978-0-691-15498-5
1090:polyhedral graphs
1086:Tait's conjecture
1082:Hamiltonian graph
1024:Lovász conjecture
973:squares of graphs
971:, on Hamiltonian
958:polyhedral graphs
936:computing it and
705:
604:pair of vertices
379:, is Hamiltonian.
348:Lovász conjecture
229:Hamiltonian graph
209:Hamiltonian cycle
170:Abraham de Moivre
111:Hamilton's puzzle
79:Hamiltonian cycle
16:(Redirected from
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138:Thomas Kirkman
127:roots of unity
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1757:Ore, Øystein
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1729:, Series B,
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1695:
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1661:
1660:, 3rd Ser.,
1657:
1654:Dirac, G. A.
1643:, retrieved
1636:the original
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1532:Tutte, W. T.
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1395:. Retrieved
1388:the original
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1354:
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1308:
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1241:(1): 55–72.
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1205:. Retrieved
1196:
1186:
1177:
1171:
1152:
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1121:
1117:
1111:
1061:induced path
1018:cubic graphs
1014:LCF notation
930:
915:
904:
891:
888:
875:simple graph
862:
858:
806:
777:
773:
770:or greater.
734:simple graph
722:
718:or greater.
657:simple graph
648:
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612:
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579:
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568:enough edges
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510:vertices is
491:
484:vertices is
479:
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449:
442:
438:
417:
406:
403:
377:binary trees
360:with cyclic
342:of a finite
340:Cayley graph
251:
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135:
115:dodecahedron
110:
107:icosian game
100:
82:
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66:
62:
59:graph theory
55:mathematical
52:
1807:: 225–226,
602:nonadjacent
584:of a graph
544:Øystein Ore
542:(1952) and
540:G. A. Dirac
409:biconnected
315:cycle graph
221:graph cycle
217:vertex tour
180:Definitions
131:quaternions
92:NP-complete
1855:Categories
1645:2005-11-28
1601:References
1542:: 99–116,
1438:Moon, J.;
1397:2012-12-10
740:vertices (
663:vertices (
471:tournament
435:line graph
384:Properties
369:flip graph
322:tournament
146:chessboard
1837:MathWorld
1767:(1): 55,
1717:: 415–416
1664:: 69–81,
1474:119358798
1440:Moser, L.
1419:: 37–41.
1248:1111.6216
978:Gray code
955:bipartite
841:−
751:≥
674:≥
556:toughness
125:based on
57:field of
1797:Pósa, L.
1590:39024286
1265:57575227
1201:Archived
944:See also
866:Kaykobad
622:) + deg(
564:distance
258:Examples
1813:0184876
1789:0118683
1781:2308928
1749:0317997
1678:0047308
1519:1503003
1511:1968197
1466:0161332
1138:0608093
917:Theorem
906:Theorem
864:Rahman–
575:closure
552:density
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158:Rudrata
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1080:planar
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331:Every
320:Every
313:Every
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94:; see
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1777:JSTOR
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1639:(PDF)
1624:(PDF)
1586:S2CID
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1470:S2CID
1391:(PDF)
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1261:S2CID
1243:arXiv
1103:Notes
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823:with
794:with
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659:with
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