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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.

Appreciate your help!

share|improve this question
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

The difference equation and initial conditions are difference equation

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}]
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)
enter image description here

Now examine the sum of f(m+1,n) x^m enter image description here

Now solve the simple algebraic-difference equation: enter image description here

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];
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 Results!

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]
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}
share|improve this answer
@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

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.

share|improve this answer
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

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