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Given an undirectd graph G, I want to cover all the edges with fewest simple paths.

For example, for a graph like this,

   B     E
   |     |

A--C--D--F--G, B--C--D--F--E is an optimum solution, whereas A--C--D--F--G , B--C , E--F is not.

Any algorithms?

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Have you tried anything at all? This smells like homework. – Blender Nov 16 '11 at 7:45
No, it is not homework stuff, I don't know if there is any constructive solution or if I have to do 'brute force' search. – shi kui Nov 16 '11 at 7:53
All right, Just found a useful article called "Simple path covers in graphs" – shi kui Nov 16 '11 at 8:03
Deciding whether one path is sufficient is NP-complete (the Hamiltonian path problem) so this problem is NP-hard. – Rafał Dowgird Nov 16 '11 at 8:28
However, there should be a simple(r) algorithm if we restrict ourselves to trees (like in the example in the question) or some other particular kind of graph – hugomg Nov 16 '11 at 12:42
up vote 2 down vote accepted

as said by @RafalDowgird in comments, finding if one path is enough is the Hamiltonian Path Problem, which is NP-Hard, and there is no known polynomial algorithm for these problems.

This leaves you with 2 options:

  1. Use heuristical solution, which might not be optimized. [example algorithm attached]
  2. use exponential solution, such as backtracking

for option one, you could try a greedy solution:

while (graph is not covered):
   pick arbitrary 2 connected not covered vertices v1,v2
   if there are none matching: 
       choose an arbitrary not covered vertex
       add an arbitrary path starting from this vertex
       choose the longest simple path from v1 to v2 [can be found with BFS/DFS]
       add this path

for option two a naive backtracking solution will be

1. find P={all possible paths}
2. create S=2^P //the power set of P
3. chose s in S such that for each s' in S: |s| <= |s'| and both s,s' cover all vertices.

note that this solution is O(2^(n!)), so though it is optimal, it is not practical.

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Thanks @amit. As you said this problem itself is NP-hard so I have to find some heuristical algorithms instead~ – shi kui Nov 17 '11 at 16:25

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