# How to solve for the analytic solution of a recurrence relation in mathematica

I have a recurrence such as following:

``````RSolve[{f[m, n] == f[m, n - 1] + f[m - 1, n],
f[0, n] == 1, f[m, 0] == 1},
f[m, n], {n}]
``````

I tried to use RSolve, but I got an error:

``````RSolve::deqx: Supplied equations are not difference equations
of the given functions.
``````

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I don't know mathematica, but the last two entries don't look like equations to me... – btilly Feb 9 '11 at 1:59
@btilly: what did you mean here? I am trying to give boundary conditions for the recurrence relation. – Qiang Li Feb 9 '11 at 2:32
@btilly the last two entries in the RSolve are the function to solve for and the free variables. As pointed out by @Alexey, the last one should be {m,n}. – Simon Feb 9 '11 at 5:42
Thanks, Simon. As I said, I don't know Mathematica. I was just looking at the error message and looking for something that /might/ fit. – btilly Feb 9 '11 at 6:01
Perhaps you may take a look at risc.jku.at/research/combinat/software/Guess/index.php – Dr. belisarius Feb 12 '11 at 14:15

Not the answer but it seems that the right form should be (note `{m, n}` at the end):

``````RSolve[{f[m, n] == f[m, n - 1] + f[m - 1, n], f[0, n] == 1, f[m, 0] == 1}, f[m, n], {m, n}]
``````

Mathematica leaves this unevaluated. I think it just cannot solve this.

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but this is a very simple function, f[m,n]=Binomial[n+m,m]. Mma cannot solve it? – Qiang Li Feb 9 '11 at 5:54
I think that most CASs struggle to solve 2-variable recurrence relations... Don't know why though, this one's not that hard. – Simon Feb 9 '11 at 6:01
@Simon: so this is a known unsolved problem in mma? – Qiang Li Feb 9 '11 at 6:33

The difference equation and initial conditions are

Mathematica (7 and 8) does not like solving it... both with and without initial conditions. The RSolve expressions are left unevaluated

``````In[1]:= RSolve[{f[m,n]==f[m,n-1]+f[m-1,n],f[0,n]==f[m,0]==1},f[m,n],{m,n}]
RSolve[{f[m,n]==f[m,n-1]+f[m-1,n]},f[m,n],{m,n}]
Out[1]= RSolve[{f[m,n]==f[-1+m,n]+f[m,-1+n],f[0,n]==f[m,0]==1},f[m,n],{m,n}]
Out[2]= RSolve[{f[m,n]==f[-1+m,n]+f[m,-1+n]},f[m,n],{m,n}]
``````

I know that Mathematica uses generating functional methods (probably among other things) to solve such recurrences, but I don't know why it fails in such a simple case.

So let's do it by hand.

Let g(x,n) be the generating function for f(m,n)

Now examine the sum of f(m+1,n) x^m

Now solve the simple algebraic-difference equation:

Which can also be done with `RSolve`

``````In[3]:= RSolve[g[x,n]-x g[x,n]==g[x,n-1]&&g[x,0]==1/(1-x),g[x,n],n];
Simplify[%,Element[n,Integers]]
Out[4]= {{g[x,n]->(1-x)^(-1-n)}}
``````

Now extract the coefficient of x^m:

``````In[5]:= SeriesCoefficient[(1 - x)^(-1 - n), {x, 0, m}]
Out[5]= Piecewise[{{(-1)^m*Binomial[-1 - n, m], m >= 0}}, 0]
``````

The binomial is simplified using

``````In[6]:= FullSimplify[(-1)^m*Binomial[-n - 1, m] == Binomial[m + n, m], Element[{n,m}, Integers]&&m>0&&n>0 ]
Out[6]= True
``````

So we finally get

This can be checked using symbolic and numeric means

``````In[7]:= ff[m_,n_]:=ff[m,n]=ff[m-1,n]+ff[m,n-1]
ff[0,_]:=1;ff[_,0]:=1
In[9]:= And@@Flatten[Table[ff[m,n]==Binomial[n+m,m],{n,0,20},{m,0,20}]]
Out[9]= True

In[10]:= {f[m,n]==f[m,n-1]+f[m-1,n],f[0,n]==f[m,0]==1}/.f->(Binomial[#1+#2,#1]&)//FullSimplify
Out[10]= {True,True}
``````
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@Qiang Li: I know you probably know how to do it by hand... but I had made such a nice notebook... – Simon Feb 9 '11 at 6:59
Of course, the 2-variable generating function is (1-x-y)^(-1)... – Simon Feb 9 '11 at 7:41
@Simon, I appreciate your effort. But you, instead of mma, did most of the work. :) – Qiang Li Feb 9 '11 at 20:39
+1, I have to look at generating functions, I've never used them. – rcollyer Feb 9 '11 at 20:42
@Qiang Li: I've found that mma is useful for doing a lot of things, and can often lead you in directions you would never have thought of. However, I have found that spending a little extra time examining the problem by hand gives superior results. But, that's true of any programming language. – rcollyer Feb 9 '11 at 20:46