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I have a mesh network as shown in figure. Now, I am allocating values to all edges in this sat network. I want to propose in my program that, there are no closed loops in my allocation. For example the constraint for top-left most square can be written as -

E0 = 0 or E3 = 0 or E4 = 0 or E7 = 0, so either of the link has to be inactive in order not to form a loop. However, in this kind of network, there are many possible loops.

For example loop formed by edges - E0, E3, E7, E11, E15, E12, E5, E1.

Now my problem is that I have to describe each possible combination of loop which can occur in this network. I tried to write constraints in one possible formula, however I was not able to succeed.

Can anyone throw any pointers if there is a possible way to encode this situation? Just for information, I am using Z3 Sat Solver.

Mesh Network

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Your problem is a variation on the undirected Hamiltonian path problem. It's an NP problem so there must be a polynomial-time reduction from it to SAT. Enumerating all possible loops and forbidding them produces a list that grows exponentially as the number of edges increases, so you need a different approach. You should be able to modify the Hamiltonian-to-SAT reduction on this page slightly to create a SAT instance that is satisfiable iff there are loops of any size. –  Kyle Jones Feb 16 '13 at 19:57
Thanks for your reply. If I fix the problem size for 4x4 network only, then will it be simple? –  Raj Feb 17 '13 at 19:53
Actually, this is not really a Hamiltonian Path problem. This is because, I don't visit every node. Instead, I visit some of the nodes which form a path from source node to destination node. Some of the nodes and links may remain inactive for a given path. –  Raj Feb 18 '13 at 17:09

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