# 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 useful to find the minimum cost for a water, telephone or electricity grid. There is Prim's algorithm or Kruskal algorithm. IMO Prim's algorithm is a bit easier to understand.

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As others have said, the minimum spanning tree (MST) will allow you to form a minimum distance sub-graph that connects all of your points.

You will first need to form a graph for your data set though. To efficiently form an undirected graph you could compute the Delaunay triangulation of your point set. The conversion from the triangulation to the graph is then fairly literal - any edge in the triangulation is also an edge in the graph, weighted by the length of the triangulation edge.

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.

Hope this helps.

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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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