## High-Level Idea

- Generate a (uniformly chosen) random spanning tree with
**N** nodes and **N - 1** edges.
- Until the requested number of edges has been reached, add an edge between any two random nodes.

## Creating the Spanning Tree

The partition-based answer by ypnos is a good start, but bias is introduced by always selecting a visited node for one end of a new edge. By randomly selecting a visited node at each iteration, nodes that are visited towards the beginning have more iterations from which they have a chance to be chosen. Therefore, earlier nodes are more likely to have a high degree (number of edges) than those picked later.

### Example of Bias

As an example, for a 4 node connected graph rather than generating a linear path graph, which is what 75% of the possible spanning trees are, this kind of bias will cause the star graph to be generated with greater than the 25% probability that it should be.

Bias isn't always a bad thing. It turns out this kind of bias is good for generating spanning trees that are similar to real world computer networks. However, in order to create a truly random connected graph the initial spanning tree must be picked uniformly from the set of possible spanning trees (see Wikipedia's Uniform Spanning Tree article).

### Random Walk Approach

One approach to generating a uniform spanning tree is through a random walk. Below is a quote from the paper Generating Random Spanning Trees More Quickly than the Cover Time by Wilson describing simple random walk algorithm.

Start at any vertex and do a simple random walk on the graph. Each time a vertex is first encountered, mark the edge from which it was discovered. When all the vertices are discovered, the marked edges form a random spanning tree. This algorithm is easy to code up, has small running time constants, and has a nice proof that it generates trees with the right probabilities.

This works well for a simple connected graph, however if you need an algorithm for a directed graph then read the paper further as it describes Wilson's Algorithm. Here is another resource for random spanning trees and Wilson's Algorithm.

## Implementation

As I was also interested in this problem, I coded Python implementations of various approaches, including the random walk approach. Feel free to take a look at the Gist of the code on GitHub.

Below is an excerpt from the code of the random walk approach:

```
# Create two partitions, S and T. Initially store all nodes in S.
S, T = set(nodes), set()
# Pick a random node, and mark it as visited and the current node.
current_node = random.sample(S, 1).pop()
S.remove(current_node)
T.add(current_node)
graph = Graph(nodes)
# Create a random connected graph.
while S:
# Randomly pick the next node from the neighbors of the current node.
# As we are generating a connected graph, we assume a complete graph.
neighbor_node = random.sample(nodes, 1).pop()
# If the new node hasn't been visited, add the edge from current to new.
if neighbor_node not in T:
edge = (current_node, neighbor_node)
graph.add_edge(edge)
S.remove(neighbor_node)
T.add(neighbor_node)
# Set the new node as the current node.
current_node = neighbor_node
# Add random edges until the number of desired edges is reached.
graph.add_random_edges(num_edges)
```