@Daniel Caballero, You said you want to find the probability matrix. Do you mean the probability vector?
I wll assume that you mean the probability vector. It is good to recognize from the problem statement that you are being asked to find the equilibrium probability distribution, i.e. the distribution which, once attained, will stay the same. It is also helpful to recognize that this is an eigenvector problem: you are finding the eigenvector with the largest eigenvalue, for the state transition matrix (or Markov transition matrix) T. But is an issue: matrix T-I is singular. But there's a way out: since the probbailities sum to 1, eight probabiliities determine the 9th one uniquely. So we can reduce the rank of the matrix by one, and it won't be singular. This will take some algebra, because can't just delete one row and one column. You have to adjust the rates that remain. You do this by replacing p2 (if you choose p2) with 1-(p1+p3+p4+p5+p6+p7+p8+p9), and then do some stuff which I forget, but which you have probably learned. (I took a course on this in 1983.) I recommend that you delete p1, p2, p6, or p7, because the other probabilities are needed to compute AbUn and RelUn. I would try deleting p2, because its row and column have the fewest off-diagonal elements, so the algebra associated with deleting it may be simpler than for the other options.
As for the graph, once you do the work above, you will have a theoretical 8x8 matrix. Then you assume a value for θpm, and plug in all the other known values. Then you solve, ie. you find the eigenvector with the biggest eigenvalue. Then add up the probabilities p4+p8=AbUn from that eigenvector, and p3+p5+p9=RelUn, and save those values, associated with the θpm which you used. Then repeat with different values of θpm. When you have a sufficient set of θpm values and associated RelUn and AbUn, plot θpm vs RelUn and θpm vs. AbUn.
