Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I'm trying to solve (find a closed-form solution to) this (Risk odds calculator) recurrence relation:

p[n,m] == 2890/7776*p[n,m-2] + 2611/7776*p[n-1,m-1] + 2275/7776*p[n-2,m],
p[n,1] == 855/1296 + 441/1296*p[n-1,1],
p[3,m] == 295/1296*p[3,m-2] + 420/1296*p[2,m-1],
p[2,m] == 55/216,
p[1,m] == 0

Mathematica's RSolve function doesn't work (I'm sure I'm using the right syntax, since I'm following the two-variable examples at http://reference.wolfram.com/mathematica/ref/RSolve.html).

In fact, RSolve won't even solve this "simpler" recursion:

p[n,m] == p[n,m-2] + p[n-1,m-1] + p[n-2,m],
p[0,m] == 1,
p[1,m] == 1,
p[n,1] == 1,
p[n,0] == 1

Is there something fundamentally hard about solving this type of recurrence relation or is Mathematica just being flaky?

The exact example I'm using:

p[n,m] == p[n,m-2] + p[n-1,m-1] + p[n-2,m], 
p[0,m] == 1, 
p[1,m] == 1, 
p[n,1] == 1, 
p[n,0] == 1 
}, p[n,m], {n,m}]

The return value is the same as my input, up to some number juggling.

On the doc page, it's under "Scope" and then "Partial Difference Equations"

share|improve this question
@user354134 Could you post your syntax and the exact examples you are following? I don't find the equivalent problems in the Mathematica help- Tnx! BTW ... tnx to those that reopened this question! –  belisarius Oct 9 '10 at 15:57
Done as reqested. –  barrycarter Oct 10 '10 at 2:03
Not sure it helps, but "p[n,m]/n^(m-2)" appears to be linear in n for all values of m, but with a non-0 intercept. –  barrycarter Oct 11 '10 at 16:32
You might also want to post this question on math.stackexchange.com. I think that mathematica is relevant on both sites. –  Peter DeWeese Oct 13 '10 at 21:44
OK, you're right: my first system of equations is incomplete, but Mathematica should be able to solve it using arbitrary constants. However, let's focus on my second/last set of equations, which is complete. I'm pretty sure solving the general form will yield the solution for the specific form. –  barrycarter Oct 16 '10 at 17:44

2 Answers 2

...just my two cents, but isn't this system of equations flawed? I.e.:

p[n,m] == 2890/7776*p[n,m-2] + 2611/7776*p[n-1,m-1] + 2275/7776*p[n-2,m]

For instance, let's try to compute p[N,2]:

p[N,2] = 2890/7776*p[N,0] + ...
       = 2890/7776*2890/7776*p[N,-2] + ...
       = ... p[N,-4] + ...

I guess you got my point. It will never reach an initial condition for an even m. Same for:

p[3,m] == 295/1296*p[3,m-2] + ...

On the opposite, the initial condition p[1,m] == 0 will never be used. Perhaps adding a definition for p[n,0] or p[n,2] would solve your problem by making it well defined.

share|improve this answer
OK, but where you say P[N,0], isn't that equal to 1 by my conditions above? I'm pretty sure this recursion works, since I can calculate it in Mathematica, albeit not in closed form. –  barrycarter Oct 13 '10 at 0:40
In your original task, are m & n one-based? If they are one-based, then there's no rule to calculate P[3,2], because both the first and the third rule try to refer to P[3,0]. If they are zero-based, then the value of P[3,0] is undefined. –  user434507 Oct 14 '10 at 23:21
Also, what happens if you try to compute p[3,1] ??? ...should it try to follow the path p[3,m] or p[n,1] ? ...both leading to different solutions. One value, several pathes ...problematic. Your problem is ill-defined in many ways. –  arnaud Oct 15 '10 at 13:33
@user354134 Could you explain how did you arrive at these eqs. from the Risk Odds Calculator? Perhaps something is loose there ... –  belisarius Oct 16 '10 at 0:10

Disclaimer: I know just a little linear algebra and some calculus. I don't know anything about Wolfram.

It might be that there's something fundamentally hard about it. The examples that you linked to are all easier than yours. For instance, look at this example:

RSolve[a[m + 1, n] - 3/4 a[m, n + 1] == 0, a[m, n], {m, n}]

All the a[m,n] are on a straight line, m+n=k for some constant k. Like say you know a[10,5]. From that you can compute a[11,4], a[12,3], etc. But they're all on a straight line. That's why the output includes some function of m+n. You could re-write it with just one variable and get the same effect:

RSolve[{a[m + 1] - 3/4 a[m] == 0, m+n=k}, a[m], {m, n}]

All the examples in that link are on a straight line, too. For every a[m,n] that you need to know, n is always a function of m. Anything of that form is easy to solve with linear algebra matrices. (Let me know if you want to know about how to do those.)

For yours, however, that isn't the case. Yours expands like a tree, not like a line. I think that that might be the difficulty.

It kind of reminds me of the difference between partial derivatives and total derivatives. That might be a good starting point.

share|improve this answer
Not sure this helps at all, but: "p[n-1,m+1]-p[n,m] == p[n,m-2] - p[n-3,m]" holds, and makes me wonder if m-n is the key here somehow. –  barrycarter Oct 11 '10 at 15:55
Those still aren't in a straight line like all the other examples. Why do you need it anyway? Just a personal challenege? If you actually need to compute it, you could just memoize 100x100 results. –  Eyal Oct 13 '10 at 7:49

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.