I have a connected directed weighted graph. The edge weights represent probabilities of moving between vertices; weights for all edges emanating from a vertex sum up to one. The graph contains two sinks: A and B. For each vertex in the graph, I want to know the probability that a walk originating there will reach A and the same for B. What kind of problem is this? How do I solve it?
This problem is of the algebra kind. For a path starting at a vertex, the probability of reaching A is the average of probabilities of reaching A from each of its neighbouring vertices, weighted by the edge weights. Let's put this into more concrete terms. Let P be the adjacency matrix for the graph. That is, P_{i,j} is the probability of moving from vertex i to vertex j. Set P_{A,A} = 1. If we take a vector of probabilities assigned to each vertex and multiply it by P, then the resulting vector contains a weighted average of each vertex's neighbours. What we are looking for is a vector v, such that P v = v and v_{A} = 1. This vector v is the eigenvector of P corresponding to the eigenvalue of 1. Does P always have such an eigenvalue? Fortunately, the PerronFrobenius theorem tells us that it does, and that this is the largest eigenvalue of P. The solution is then to form the adjacency matrix P and find the eigenvector corresponding to its largest eigenvalue. There is also an approximate solution. If we take a vector x of vertex probabilities, with x_{A} = 1, and the other elements set to 0, then P^{k} x will converge to v as k goes to infinity. P^{k} might be easier to compute for small values of k than the eigenvector. ExampleLet's look at the following simple graph: If we order the vertices alphabetically, then the matrix P corresponding to the graph is: This matrix has an eigenvalue equal to 1, and the corresponding eigenvector is: [1 0 70/79 49/79]. That is, the exact probability of reaching A from C is 70/79, and from D it is 49/79. If you work out the answer for B, it comes out to 9/79 and 30/79, which is exactly what we expect. The value of P^{16} [1 0 0 0] is approximately [1 0 0.886 0.62] and is correct to 6 decimal places. 

