I'm searching for an algorithm to find pairs of adjacent nodes on a hexagonal (honeycomb) graph that minimizes a cost function.

- each node is connected to three adjacent nodes
- each node "i" should be paired with
**exactly one**neighbor node "j". each pair of nodes defines a cost function

c = pairCost( i, j )

The total cost is then computed as

totalCost = 1/2 sum_{i=1:N} ( pairCost(i, pair(i) ) )

Where pair(i) returns the index of the node that "i" is paired with. (The sum is divided by two because the sum counts each node twice). My question is, **how do I find node pairs that minimize the totalCost?**

The linked image should make it clearer what a solution would look like (thick red line indicates a pairing):

Some further notes:

- I don't really care about the outmost nodes
- My cost function is something like ||
**v**(i) -**v**(j) || (distance between vectors associated with the nodes) - I'm guessing the problem might be NP-hard, but I don't really need the truly optimal solution, a good one would suffice.
- Naive algos tend to get nodes that are "locked in", i.e. all their neighbors are taken.

Note: I'm not familiar with the usual nomenclature in this field (is it graph theory?). If you could help with that, then maybe that could enable me to search for a solution in the literature.