# Algorithm to connect all dots with the minimum total distance

I have a set of points and a distance function applicable to each pair of points. I would like to connect ALL the points together, with the minimum total distance. Do you know about an existing algorithm I could use for that ?

Each point can be linked to several points, so this is not the usual "salesman itinerary" problem :)

Thanks !

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This could be interpreted as a minimum-weight spanning tree problem. I'm not sure that's the best way to approach it but it's one way. –  biziclop Feb 27 '12 at 19:35
If the distance metric follows D(x,z) <= D(x,y) + D(y,z) for every three points x,y&z then basically connecting every pair points would give total minimum distance. I think you need to refine your question a bit. –  ElKamina Feb 27 '12 at 19:36
The distance metric could be the sum of all connections' lengths. –  Jim Blackler Feb 27 '12 at 19:38
Sorry guys my formulation of the question was not very clear. You're right @biziclop, this is a minimum-weight spanning tree problem. I didn't know this term. –  Blacksad Feb 27 '12 at 19:41
@Blacksad Sometimes all we need is the name of the concept we're after. :) –  biziclop Feb 27 '12 at 22:35

What you want is a Minimum spanning tree.

The two most common algorithms to generate one are:

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The algorithm you are looking for is called minimum spanning tree. It's good to find the minimum cost for a water, telephone, electricity grid. There is Prim's algorithm or Kruskal algorithm. IMO Prim's algorithm is a bit easier to understand.

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Take a look at the Dijkstra's algorithm:

Dijkstra's algorithm, conceived by Dutch computer scientist Edsger Dijkstra in 1956 and published in 1959, is a graph search algorithm that solves the single-source shortest path problem for a graph with nonnegative edge path costs, producing a shortest path tree. This algorithm is often used in routing and as a subroutine in other graph algorithms.

http://en.wikipedia.org/wiki/Dijkstra's_algorithm

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There are efficient algorithms for both the MST (Prim's/Kruskal's `O(E*log(V))`) and Delaunay triangulation (Divide and Conquer `O(V*log(V))`) phases, so efficient overall approaches are possible.