- Hamiltonian path
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This article is about the overall graph theory concept of a Hamiltonian path. For the specific problem of determining whether a Hamiltonian path or cycle exists in a given graph, see Hamiltonian path problem.
In the mathematical field of graph theory, a Hamiltonian path (or traceable path) is a path in an undirected graph that visits each vertex exactly once. A Hamiltonian cycle (or Hamiltonian circuit) is a cycle in an undirected graph that visits each vertex exactly once and also returns to the starting vertex. Determining whether such paths and cycles exist in graphs is the Hamiltonian path problem, which is NP-complete.
Hamiltonian paths and cycles are named after William Rowan Hamilton who invented the Icosian game, now also known as Hamilton's puzzle, which involves finding a Hamiltonian cycle in the edge graph of the dodecahedron. Hamilton solved this problem using the Icosian Calculus, an algebraic structure based on roots of unity with many similarities to the quaternions (also invented by Hamilton). This solution does not generalize to arbitrary graphs. However, despite being named after Hamilton, Hamiltonian cycles in polyhedra had also been studied a year earlier by Thomas Kirkman.[1]
Contents
Definitions
A Hamiltonian path or traceable path is a path that visits each vertex exactly once. A graph that contains a Hamiltonian path is called a traceable graph. A graph is Hamiltonian-connected if for every pair of vertices there is a Hamiltonian path between the two vertices.
A Hamiltonian cycle, Hamiltonian circuit, vertex tour or graph cycle is a cycle that visits each vertex exactly once (except the vertex that is both the start and end, and so is visited twice). A graph that contains a Hamiltonian cycle is called a Hamiltonian graph.
Similar notions may be defined for directed graphs, 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").
A Hamiltonian decomposition is an edge decomposition of a graph into Hamiltonian circuits. This is one of the known but unsolved problems.[clarification needed]
Examples
- a complete graph with more than two vertices is Hamiltonian
- every cycle graph is Hamiltonian
- every tournament has an odd number of Hamiltonian paths[citation needed]
- every platonic solid, considered as a graph, is Hamiltonian[citation needed]
- every prism is Hamiltonian[citation needed]
- The Deltoidal hexecontahedron is the only non-hamiltonian Archimedean dual[citation needed]
- Every antiprism is Hamiltonian[citation needed]
- A maximal planar graph with no separating triangles is Hamiltonian.[citation needed]
Properties
Any Hamiltonian cycle can be converted to a Hamiltonian path by removing one of its edges, but a Hamiltonian path can be extended to Hamiltonian cycle only if its endpoints are adjacent.
The line graph of a Hamiltonian graph is Hamiltonian. The line graph of an Eulerian graph is Hamiltonian[clarification needed].
A tournament (with more than 2 vertices) is Hamiltonian if and only if it is strongly connected.
A Hamiltonian cycle may be used as the basis of a zero-knowledge proof.
Number of different Hamiltonian cycles for a complete graph = (n-1)! / 2.
Number of different Hamiltonian cycles for a complete directed graph = (n-1)!.
Bondy–Chvátal theorem
The best vertex degree characterization of Hamiltonian graphs was provided in 1972 by the Bondy–Chvátal theorem, which generalizes earlier results by G. A. Dirac (1952) and Øystein Ore. In fact, both Dirac's and Ore's theorems are less powerful than what can be derived from Pósa's theorem (1962). Dirac and Ore's theorems basically state that a graph is Hamiltonian if it has enough edges. First we have to define the closure of a graph.
Given a graph G with n vertices, the closure cl(G) is uniquely constructed from G by successively adding for all nonadjacent pairs of vertices u and v with degree(v) + degree(u) ≥ n[clarification needed] the new edge uv.
Bondy–Chvátal theorem
- A graph is Hamiltonian if and only if its closure is Hamiltonian.
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.
Dirac (1952)
- A simple graph with n vertices (n ≥ 3) is Hamiltonian if each vertex has degree n/2 or greater.[2]
Ore (1960)
- A graph with n vertices (n ≥ 3) is Hamiltonian if, for each pair of non-adjacent vertices, the sum of their degrees is n or greater (see Ore's theorem).
The following theorems can be regarded as directed versions:
Ghouila-Houiri (1960)
- A strongly connected simple directed graph with n vertices is Hamiltonian if some vertex has a full degree smaller than n.
Meyniel (1973)
- A strongly connected simple directed graph with n vertices is Hamiltonian if the sum of full degrees of some two distinct non-adjacent vertices is smaller than 2n − 1.
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.
See also
- Barnette's conjecture, an open problem on Hamiltonicity of cubic bipartite polyhedral graphs
- Eulerian path, a path through all edges in a graph
- Grinberg's theorem giving a necessary condition for planar graphs to have a Hamiltonian cycle
- Knight's tour, a Hamiltonian cycle in the knight's graph
- Hamiltonian path problem, the computational problem of finding Hamiltonian paths
- Hypohamiltonian graph, a non-Hamiltonian graph in which every vertex-deleted subgraph is Hamiltonian
- LCF notation for Hamiltonian cubic graphs.
- Lovász conjecture that vertex-transitive graphs are Hamiltonian
- Pancyclic graph, graphs with cycles of all lengths including a Hamiltonian cycle
- Snake-in-the-box, the longest induced path in a hypercube
- Steinhaus–Johnson–Trotter algorithm for finding a Hamiltonian path in a permutohedron
- Tait's conjecture (now known false) that 3-regular polyhedral graphs are Hamiltonian
- Travelling salesman problem
Notes
References
- Berge, Claude; Ghouila-Houiri, A. (1962), Programming, games and transportation networks, New York: John Wiley & Sons, Inc.
- DeLeon, Melissa, "A Study of Sufficient Conditions for Hamiltonian Cycles". Department of Mathematics and Computer Science, Seton Hall University
- Dirac, G. A. (1952), "Some theorems on abstract graphs", Proceedings of the London Mathematical Society, 3rd Ser. 2: 69–81, doi:10.1112/plms/s3-2.1.69, MR0047308
- Graham, Ronald L., Handbook of Combinatorics, MIT Press, 1995. ISBN 9780262571708.
- Hamilton, William Rowan, "Memorandum respecting a new system of roots of unity". Philosophical Magazine, 12 1856
- Hamilton, William Rowan, "Account of the Icosian Calculus". Proceedings of the Royal Irish Academy, 6 1858
- Meyniel, M. (1973), "Une condition suffisante d'existence d'un circuit hamiltonien dans un graphe orienté", Journal of Combinatorial Theory, Ser. B 14 (2): 137–147, doi:10.1016/0095-8956(73)90057-9
- Ore, O "A Note on Hamiltonian Circuits." American Mathematical Monthly 67, 55, 1960.
- Peterson, Ivars, "The Mathematical Tourist". 1988. W. H. Freeman and Company, NY
- Pósa, L. A theorem concerning hamilton lines. Magyar Tud. Akad. Mat. Kutato Int. Kozl. 7(1962), 225–226.
- Chuzo Iwamoto and Godfried Toussaint, "Finding Hamiltonian circuits in arrangements of Jordan curves is NP-complete," Information Processing Letters, Vol. 52, 1994, pp. 183–189.
External links
Categories:- Computational problems in graph theory
- NP-complete problems
- Graph theory objects
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