# Algorithm for finding circular mappings of maximal size

I have nine sets of 500 objects each. Although the sets are independent, I assume that the sets share a core of common objects. However, one and the same object may have a different name (index) depending on the set. But I can measure the pairwise distance between two objects.

Based on the pairwise distances, I already computed optimal mappings between objects of two sets for all pairs of sets. So, for every pair of sets, I can say the correspondence between any two objects.

Now I want to detect closed mapping circles, e.g. { 5 (set 1) -> 13 (set 2) -> 24 (set 3) -> 5 (set 1) }, i.e. object 5 of set 1 maps to object 13 of set 2, which maps to 24 in set 3, which then maps back to object 5 of set 1. I need this form of a circular mapping to argue that the objects are essentially the same.

Of course, in an ideal world, I could identify a majority of circles that span all nine sets. However, common objects between 3-9 sets are also interesting. Thus, I want an exhaustive listing.

Do you know an algorithm to perform this task, or how this problem is termed in combinatorial mathematics!?

As a heuristic approach, I would start by determining circles within all combinations of 3 sets and then combine these results for larger combinations of sets.

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Not sure I am following, are you looking for a cycle that includes most objects, while "jumping" between sets? It smells a lot like Hamiltonian Path Problem I am afraid :| –  amit Dec 6 '12 at 9:29
I can't really follow the problem description, but it sounds like you are looking for isomorphisms between the sets? –  phant0m Dec 6 '12 at 9:49
Is there a specific point of my explanations, which is hard to follow? maybe I could clarify... –  user1881788 Dec 6 '12 at 9:49
Essentially, what I am looking for seems to be the maximum clique problem. –  user1881788 Dec 6 '12 at 10:22
Can one object be mapped to multiple objects of a target set? (is the mapping a function or a relation?) –  Asiri Rathnayake Dec 6 '12 at 11:23

If I follow your description correctly, it seems you'll like to find correspondences between the sets. Will this algorithm work for you.

`````` 1. Intialize a hashmap H
2. Initialize key frequency map U = {}
3. for each set i
4.    for each element e in set i
5.        H.insert {e.key, {i, ...}}
6.        if U.contain(e.key)
7.            c = U.get(e.key)
8.           U.update(e.key,  c + 1)
9.        else
10.            U.insert(e.key,  1)
11.        endif
12.    endfor
13. endfor
``````

Line 5 will insert an element into the map H. Elements with the same key are stored in a linked list. You can find the longest chain by finding the the key with the largest frequency in U. Then by doing H.get(key), you'll get back the list. By linking the last element to the first, you'll obtain the cycle you seek.

I hope this helps.

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