This is essentially the problem of connecting n destinations with the minimal amount of road possible.

The input is a set of vertices (a,b, ... , n)

The weight of an edge between two vertices is easily calculated (example the cartesian distance between the two vertices)

I would like an algorithm that given a set of vertices in euclidian space, returns a set of edges that would constitute a connected graph and whose total weight of edges is as small as it could be.

**In graph language, this is the Minimum Spanning Tree of a Connected Graph.**

With brute force I would have:

- Define all possible edges between all vertices - say you have n vertices, then you have n(n-1)/2 edges in the complete graph
- A possible edge can be on or off (2 states)
- Go through all possible edge on/off combinations: 2^(n(n-1)/2)!
- Ignore all those that would not connect the graph
- From the remaining combinations, find the one whose sum of edge weights is the smallest of all

I understand this is an NP-Hard problem. However, realistically for my application, I will **have a maximum of 11 vertices**. I would like to be able to solve this on a typical modern smart phone, or at the very least on a small server size.

As a second variation, I would like to obtain the same goal, with the restriction that each vertex is connected to a maximum of one other vertex. Essentially obtaining a single trace, starting from any point, and finishing at any other point, as long as the graph is connected. There is no need to go back to where you started. **In graph language, this is the Open Euclidian Traveling Salesman Problem.**

Some pseudocode algorithms would be much helpful.