You don't need `networkX`

to solve the problem, `numpy`

can do it if you understand the math behind it. A undirected, unweighted graph can always be represented by a [0,1] adjacency matrix. `nth`

powers of this matrix represent the number of steps from `(i,j)`

after `n`

steps. We can work with a Markov matrix, which is a row normalized form of the adj. matrix. Powers of this matrix represent a random walk over the graph. If the graph is small, you can take powers of the matrix and look at the index `(start, end)`

that you are interested in. Make the final state an absorbing one, once the walk hits the spot it can't escape. At each power `n`

you get probability that you'll have diffused from `(i,j)`

. The hitting time can be computed from this function (as you know the *exact* hit time for discrete steps).

Below is an example with a simple graph defined by the edge list. At the end, I plot this hitting time function. As a reference point, this is the graph used:

```
from numpy import *
hit_idx = (0,4)
# Define a graph by edge list
edges = [[0,1],[1,2],[2,3],[2,4]]
# Create adj. matrix
A = zeros((5,5))
A[zip(*edges)] = 1
# Undirected condition
A += A.T
# Make the final state an absorbing condition
A[hit_idx[1],:] = 0
A[hit_idx[1],hit_idx[1]] = 1
# Make a proper Markov matrix by row normalizing
A = (A.T/A.sum(axis=1)).T
B = A.copy()
Z = []
for n in xrange(100):
Z.append( B[hit_idx] )
B = dot(B,A)
from pylab import *
plot(Z)
xlabel("steps")
ylabel("hit probability")
show()
```