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The only difference I could think of for the question is that in the Travelling Salesman Problem (TSP) I need to find a minimum permutation of all the vertices in the graph and in Shortest Paths problem there is no need to consider all the vertices we can search the states space for minimum path length routes can anyone suggest more differences.

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Interview question? –  Ray Toal Oct 14 '11 at 5:45

3 Answers 3

up vote 10 down vote accepted

You've already called out the essential difference: the TSP is to find a path that contains a permutation of every node in the graph, while in the shortest path problem, any given shortest path may, and often does, contain a proper subset of the nodes in the graph.

Other differences include:

  • The TSP solution requires its answer to be a cycle.
  • The TSP solution will necessarily repeat a node in its path, while a shortest path will not (unless one is looking for shortest path from a node to itself).
  • TSP is an NP-complete problem and shortest path is known polynomial-time.

If you are looking for a precise statement of the difference I would say you just need to replace your idea of the "permuation" with the more technical and precise term "simple cycle visiting every node in the graph", or better, "Hamilton cycle":

The TSP requires one to find the simple cycle covering every node in the graph with the smallest weight (alternatively, the Hamilton cycle with the least weight). The Shortest Path problem requires one to find the path between two given nodes with the smallest weight. Shortest paths need not be Hamiltonian, nor do they need to be cycles.

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yes that is what i could find but i need a more general difference that is more logical and sound –  AnkitSablok Oct 14 '11 at 5:37
    
can u tell me the answer to this question if an algorithm takes lg(n) microseconds to solve a problem we need to determine what is the maximum size of the problem we can solve using this algorithm in 1 second –  AnkitSablok Oct 14 '11 at 6:25
    
Yes, assuming that the complexity was exactly lg(n) steps (as opposed to, say, 5lg(n)+1000 steps. If T(n) = lg(n) microseconds, then T(n) = (10^-6)(lg(n)) seconds, or lg(n) = (10^6)T(n) Let T(n) = 1 so lg(n) = 10^6 or 2^lg(n) = 2^(10^6) meaning n = two to the one millionth power. That number is beyond human comprehension IMHO. –  Ray Toal Oct 14 '11 at 6:44

In TSP, you need to return to your starting point. This complicates the problem immensely.

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I think in TSP we have a path from every vertex to every other vertex and considering the undirected paths i think we can reach there isnt it? –  AnkitSablok Oct 14 '11 at 5:31
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Yes, but a TSP could also be constrained in some ways - for instance with directed paths, weighted paths, and vertices with no paths between them. It's all variations of the same problem. –  Tobbe Oct 14 '11 at 5:35
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I think this is a completely misleading answer. What complicates the problem immensely is having to find a path that visits all nodes, rather than having to return to the starting node (e.g. see Hamilton path, which is also NP-complete, but doesn't require finding a cycle). –  3lectrologos Jan 11 '13 at 13:05

With the shortest path problem you consider paths between two nodes. With the TSP you consider paths between all node. This makes the latter much more difficult.

Consider two paths between nodes A and B. One over D the other one of C. Let the one over C be the longer path. In the Shortest Path problem this path can get immediately discarded. In the TSP it is perfectly possible that this path is part of the over all solution, because you'll have to visit C and visiting it later might be even more expensive.

Therefor you can't break down the TSP in similar but smaller sub-problems.

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