# Difference between Hamiltonian path and ST

I was reading up algorithms for finding the minimum spanning tree(in case of weighted graphs) and for finding if a graph has a hamiltonian path(which depends on the presence of a hamiltonian cycle). I got everything messed up. So whats the difference between a hamiltonian path and a spanning tree? Both cover all the vertices in the graph. While we can have efficient algorithms to find a spanning tree(perhaps a minimum spanning tree), why cant we have algorithms for finding a hamiltonian circuit?? We can keep on adding and removing one edge at a time till we reach a cycle and perhaps, we could find a hamiltonian cycle??

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The two problems are quite different. Think of the minimum spanning tree as the problem of connecting places where you only have to pay once to build the road, but you can use it as many times as you like. It's easy to come up with the cheapest configuration of roads (e.g. by Kruskal's algorithm) that allows you to travel from any place to any other.

The Hamiltonian cycle, on the other hand, wants you to minimize the actual travel distance, i.e. every move from one place to another counts. (It also asks you never to visit a place twice, but that's a minor detail.) This problem is fundamentally non-local, in the sense that you cannot tell whether you're doing the right thing just by locally exploring the options for the next step. By comparison, the greedy MST algorithm is guaranteed to pick the right next edge to add to the tree at every step.

By the way, nobody says that "we cannot have efficient algorithms for HP". It might be that we just haven't found one yet :-)

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That's not true because there is the christofides algorithm to solve a travel-salesman problem with a guarantee to be within 3/2 of the optimum. A hp is a (cheap) approximation of the tsp problem. Maybe it's easier to use a space-filling-curve. –  Phpdevpad Jul 23 '11 at 16:12
According to Wikipedia, Christofides only works for Euclidean weighted graphs, though. There are of course many special cases where TSP or HP can be done efficiently. –  Kerrek SB Jul 23 '11 at 17:07
Kerrek: Do you mean it must satisified the triangle inequality? Here is a link scribd.com/doc/19417995/Euclidean-vs-nonEuclidean-Geometry. But I can't think of a real world application? Do you mind to tell me more? Do you check for a triangle inequality? –  Phpdevpad Jul 23 '11 at 17:17
Yeah, the triangle inequality implies that your graph lives isometrically in euclidean space. You gain a bit of local information from that because you know that A->B->C will always take at least as long as A->C, which you don't know in a general weighted graph. E.g. if A->B and B->C cost 1, but A->C costs 10, you would improve by replacing AC with ABC, but under the euclidean assumption you'd never need to bother testing that. –  Kerrek SB Jul 23 '11 at 17:29
By the way, this has nothing to do with "non-euclidean geometry" in the differential geometry sense. Geometry in the latter sense always satisfies a triangle inequality locally; it's just not required to be locally flat. –  Kerrek SB Jul 23 '11 at 17:30

A hamiltonian path and especially a minimum hamiltonian cycle is useful to solve a travel-salesman-problem i.e. a shortest trip. A fast solution is looking like a hilbert curve a special kind of a space-filling-curve also uses to reduce the space complexity and for efficient addressing. A mst is like connecting all vertices together with cheapest cost to connect (i.e. travel) no matter of the order or crossing. It's useful to solve a problem like finding roads, finding water-canal, finding internet-cable.

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Both problems want to connect all vertices to each other.

For a minimum spanning tree you don't care to which vertex a vertex a is connected, so you can just connect a to the closest vertex. Since you only connect vertices that are not connected yet, this gives a tree, and you have your algorithm.

For a hamiltonian path however, you do care to which vertex (say b) you connect a vertex a, as you cannot use b again (otherwise it's no path anymore). So in order to determine to what vertex you should connect a, you have to try all possibilities and see what happends. That is, no one has found an efficient way yet, that of course does not automatically means there is none.

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In hamiltonian path, all vertices except source and sink have a degree of 2. That is not necessarily the case with MST (or ST, if you want it).

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