What is dynamic programming algorithm for finding a Hamiltonian cycle in a undirected graph? I have seen somewhere that there exists a algorithm with O(n*2^n) time complextity

There is indeed an O(n2^{n}) dynamicprogramming algorithm for finding Hamiltonian cycles. The idea, which is a general one that can reduce many O(n!) backtracking approaches to O(n^{2}2^{n}) or O(n2^{n}) (at the cost of using more memory), is to consider subproblems that are sets with specified "endpoints". Here, since you want a cycle, you can start at any vertex. So fix one, call it As with most dynamic programming problems, once you define the subproblems the rest is obvious: Loop over all the 2^{n} sets S of vertices in any "increasing" order, and for each v in each such S, you can compute
Finally, there is a Hamiltonian cycle iff there is a vertex If you want the actual Hamiltonian cycle instead of just deciding whether one exists or not, make 


I can't pluck out that particular algorithm, but there is more about Hamiltonian Cycles on The Hamiltonian Page than you will likely ever need. :)


