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Can some one tell me the difference between hamiltonian path and euler path. They seem similar!

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I have removed the C/C++ tags. Feel free to add them back if you are actually looking for some sort of code for algorithms regarding euler/hamiltonian paths. –  Aryabhatta Jul 16 '10 at 22:10
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6 Answers

up vote 28 down vote accepted

A Euler path is a path that crosses every edge exactly once without repeating, if it ends at the initial vertex then it is a Euler cycle.

A Hamiltonian path passes through each vertex (note not each edge), exactly once, if it ends at the initial vertex then it is a Hamiltonian cycle.

In a Euler path you might pass through a vertex more than once.

In a Hamiltonian path you may not pass though all edges.

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from: pballew.net/graphs.html Notice that for an Euler path you may visit each vertex more than once and in a Hamilton path it is not necessary to travel every edge. –  NG. Jul 16 '10 at 21:41
    
Added to the answer thanks @SB –  Chris Diver Jul 16 '10 at 21:44
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IIRC, it's easy to find if there's a Euler path (or cycle), but whether a graph has a Hamiltonian is NP-complete. –  David Thornley Jul 16 '10 at 21:58
    
Yes, I believe there are certain properties of a Euler path which you can use to prove a graph has a Euler path without an algorithm to traverse it. Finding a Hamiltonian path is an NP-complete, i think the algorithm involves trial and error. I thought this would be beyond the scope of the original question to add it to the answer, the OP is obviously new to graph theory :D It's been a while for me, I might dig out my old books. –  Chris Diver Jul 17 '10 at 2:48
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Eulerian path must visit each edge exactly once, while Hamiltonian path must visit each vertex exactly once.

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A Hamiltonian path visits every node (or vertex) exactly once, and a Eulerian path traverses every edge exactly once.

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They are related but are neither dependent nor mutually exclusive. If a graph has an Eurler cycle, it may or may not also have a Hamiltonian cyle and vice versa.


Euler cycles visit every edge in the graph exactly once. If there are vertices in the graph with more than two edges, then by definition, the cycle will pass through those vertices more than once. As a result, vertices can be repeated but edges cannot.

Hamiltonian cycles visit every vertex in the graph exactly once (similar to the travelling salesman problem). As a result, neither edges nor vertices can be repeated.

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You are conflating paths and circuits. A Hamiltonian/Eulerian circuit is a path/trail of the appropriate type that also starts and ends at the same node. –  Yaniv Feb 8 '13 at 0:47
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Graph Theory Definitions

(In descending order of generality)

  • Walk: a sequence of edges where the end of one edge marks the beginning of the next edge

  • Trail: a walk which does not repeat any edges. All trails are walks.

  • Path: a walk where each vertex is traversed exactly once. (paths used to refer to open walks, the definition has changed now) The property of traversing vertices just once means that edges are also crossed just once, hence all paths are trails.

Hamiltonian paths & Eulerian trails

  • Hamiltonian path: visits every vertex in the graph (exactly once, because it is a path)

  • Eulerian trail: visits every edge in the graph exactly once (because it is a trail, vertices may well be crossed more than once.)

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Euler path is a graph using every edge(NOTE) of the graph exactly once. Euler circuit is a euler path that returns to it starting point after covering all edges.

While hamilton path is a graph that covers all vertex(NOTE) exactly once. When this path returns to its starting point than this path is called hamilton circuit.

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