# Graph and permutation problem

I have a graph (with nodes and edges) containing symmetry and a group of permutations to label the nodes so no edges are changed (automorphisms). Now I would like to determine for which nodes a permutation exchanges two equivalent (i.e. nodes with the same color or symmetry class) neighboring nodes.

When the nodes with equivalent neighbors stay the same, simply checking if the neighbors are exchanged in the permutation is enough. However, when the nodes with equivalent neighbors are also permuted (i.e. there are multiple nodes with the same color/symmetry class with the same equivalent neighbors), the problem becomes more complex.

Is there any known algorithm for such a problem?

Some remarks: The graph has no coordinates, it's a topology only

An example:

Identity permutation: http://imagebin.ca/view/2vAOi0I.html

There are 384 automorphic permutations: http://pastebin.org/157954

Simple example where the permutation inverts nodes 5 & 23: http://imagebin.ca/view/myQCvZnp.html

As long as 5 and 23 remain in the same place it is easy to determine if they are inverted (compared to the identity permutation). However, when these points are also interchanged it becomes more difficult.

Difficult example, permutation 67: http://imagebin.ca/view/9gl-Wmzt.html

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I'm having a little trouble following your description; do you want an algorithm to find graph automorphisms? Or one to test whether a given permutation is an automorphism? –  Rob Lachlan Apr 18 '10 at 22:12
I've added an example to make my question more clear –  timvdm Apr 18 '10 at 23:34
Your "simple example where the permutation inverts nodes 5 & 23" doesn't invert 5 and 23, the only non-identity mapping is 25 <-> 21 and 22 <-> 24. –  Keith Randall Apr 19 '10 at 3:26
5 and 23 remain in the correct place but their neighbors (25,21 for 5 and 22,24 for 23) are exchanged. This is what I need to determine. –  timvdm Apr 19 '10 at 12:49

I don't think your problem is well-defined. Imagine the following graph:

``````      1
/ \
/   \
2     3
/ \   / \
4   5 6   7
``````

Now consider the two automorphisms that swap the two subtrees of 1. automorphism A: 1<->1, 2<->3, 4<->6, and 5<->7 automorphism B: 1<->1, 2<->3, 4<->7, and 5<->6

Which one of these "inverts" the children of 2? Because 2 gets mapped to 3, we have to decide whether the natural correspondence is 4-6 and 5-7, or 4-7 and 5-6. But we have no information we can use to decide this fact.

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