How can I find the number of Hamiltonian cycles in a complete undirected graph?

Can someone explain how to find the number of Hamiltonian cycles in a complete undirected graph?

Wikipedia says that the formula is (n-1)!/2, but when I calculated using this formula, K3 has only one cycle and K4 has 5. Was my calculation incorrect?

• You have made an error when you have calculated the total number of cycles. A Hamiltonian cycle must include all the edges. k4 has only 3 such cycles and in total it has 5 cycles, so the formula is correct. – Anubhav Apr 19 '13 at 17:30

Since the graph is complete, any permutation starting with a fixed vertex gives an (almost) unique cycle (the last vertex in the permutation will have an edge back to the first, fixed vertex. Except for one thing: if you visit the vertices in the cycle in reverse order, then that's really the same cycle (because of this, the number is half of what permutations of (n-1) vertices would give you).

e.g. for vertices 1,2,3, fix "1" and you have:

123 132

but 123 reversed (321) is a rotation of (132), because 32 is 23 reversed.

There are (n-1)! permutations of the non-fixed vertices, and half of those are the reverse of another, so there are (n-1)!/2 distinct Hamiltonian cycles in the complete graph of n vertices.

• a nice explanation – avd Sep 7 '09 at 4:40
• I asked this questions in relation to a last year Code Jam Question. But I am still not able to figure out the algorithm Can u please explain this Code Jam question code.google.com/codejam/contest/dashboard?c=32004#s=p2 – avd Sep 7 '09 at 4:45
• I'd generate all the permutations of 2...n where 2 comes in the first half, and skip over those that give one of the forbidden edges, i.e. if your permutations is 4235 (meaning the cycle 142351...) then skip it if 14 42 23 35 or 51 are forbidden. You can do this as you generate the permutations e.g. if 14 was forbidden, then you would have stopped at "4..." – Jonathan Graehl Sep 7 '09 at 5:16
• But if number of vertices is very large say 30 then generating all permutations i.e. 29!/2 is computationally very expensive – avd Sep 7 '09 at 5:21
• One more thing why did u say "where 2 comes in the first half"? What does this mean? – avd Sep 7 '09 at 5:27

In answer to your Google Code Jam comment, see this SO question

I think when we have a Hamiltonian cycle since each vertex lies in the Hamiltonian cycle if we consider one vertex as starting and ending cycle . we should use 2 edges of this vertex.So we have (n-1)(n-2)/2 Hamiltonian cycle because we should select 2 edges of n-1 edges which linked to this vertex.