Talk:Fuss–Catalan number

Suggestion1

Couple of things to add that I'm not able to do properly... 1 - Am(1,x) this is Pascal's triangle (rotated), makes more sense when you plot it out. 2 - The generating function satisfies

 f(x) = (1+x.f(x)^(p/r))^r .. see Wojciech Mlotkowski's paper

This can give links to binomial distribution, and generating functions...

-- Above comments have been completed 13:45, 14 January 2014 (UTC) bbloodaxe  — Preceding unsigned comment added by Bbloodaxe (talk • contribs)  

Suggestion 2

I'm interested in why the following was changed from:

snippet

Let the ordinary generating function with respect to the index be defined as follows

${\displaystyle B_{p,r}(z):=\sum _{m=0}^{\infty }A_{m}(p,r)z^{m}}$, then the Wojciech Mlotkowski paper (see references), shows that as

${\displaystyle A_{m+1}(p,1)=A_{m}(p,p)}$ then it directly follows that ${\displaystyle B_{p,1}(z)=1+zB_{p,p}(z)}$.

This can extended by using Lambert's equivalence ${\displaystyle B_{p,1}(z)^{r}=B_{p,r}(z)}$ to the general generating function, for all the Fuss-Catalan numbers:

${\displaystyle B_{p,r}(z)=[1+zB_{p,r}(z)^{p/r}]^{r}}$.

to

snippet

Let the ordinary generating function with respect to the index be defined as follows

${\displaystyle B_{p,r}(z):=\sum _{m=0}^{\infty }A_{m}(p,r)z^{m}}$.

An immediate consequence of the representation as a Gamma Function ratio is

${\displaystyle A_{m}(p,p)=A_{m+1}(p,1)}$.

Then the Wojciech Mlotkowski paper (see references), shows that ${\displaystyle B_{p,1}(z)=1+zB_{p,p}(z)}$. This can extended by using Lambert's equivalence ${\displaystyle B_{p,1}(z)^{r}=B_{p,r}(z)}$ to:

${\displaystyle B_{p,r}(z)=[1+zB_{p,r}(z)^{p/r}]^{r}}$.

question

I did not follow Mlotkowski exactly, instead I paraphrased it, and also checked with him that the generral generating function is correct. This was the case. That said I feel the current repreaentation needs improving.

• 1 - the Mlotkowski paper makes no claim for Gamma Function ratio being involved with ${\displaystyle A_{m}(p,p)=A_{m+1}(p,1)}$, it comes from equations 2.2 & 2.3 in his paper. It may well be a consequence of such, but that was not the presented logic.
• 2 - the Mlotkiski paper does not show ${\displaystyle B_{p,1}(z)=1+zB_{p,p}(z)}$. This is a a logical consequence that ${\displaystyle A_{m}(p,p)=A_{m+1}(p,1)}$, and merely arrived at by substitution into the generating formula ${\displaystyle B_{p,r}(z):=\sum _{m=0}^{\infty }A_{m}(p,r)z^{m}}$. I will agree that the paper shows a similar formula, namely ${\displaystyle B_{p,1}(z)=1+zB_{p,1}(z)^{p}}$ equation 3.3, and the two are equivalent, but only after the Lambert equation is used, and as such the paper has a more developed version of the formula.
• 3 - The simpler, and easier to understand, method is to use recurance relationship ${\displaystyle A_{m}(p,r)=A_{m}(p,r-1)+A_{m-1}(p,p+r-1)}$ coupled with ${\displaystyle A_{m}(p,0)=0}$ when r=1 shows ${\displaystyle A_{m}(p,p)=A_{m+1}(p,1)}$. From this equivalence and the generating function definition it logically follows that ${\displaystyle B_{p,1}(z)=1+zB_{p,p}(z)}$ (no proof needed here). The real mathematical magic comes from using Lambert's equivalence, this is a result I simply lifted from my corespondance with him (it is also specifically mentioned in "DENSITIES OF THE RANEY DISTRIBUTIONS" arXiv:1211.7259v1 [math.PR] 30 Nov 2012, equation 5).

I am reluctant to change this section back as I do not know who changed it, why they changed it, they may well know far more than me!!! Bbloodaxe (talk) 14:43, 14 January 2014 (UTC) bbloodaxe

Modified to keep Gamma ratio comments, and conform with previous logic Bbloodaxe (talk)

Suggestion 3

I think this article may actually be about Raney numbers... Some of the literature suggests that Fuss-Catalan is given by

${\displaystyle A_{m}(p)={\frac {1}{mp+1}}{\binom {mp+1}{m}}}$

see Anderson Rational Catalan Combinatorics^[1], and articles on Raney numbers too mentioned in article. An alternative is to see N I Fuss work (1791 ish)"Solutio quaestionis, quot modis polygonum n laterum in polygona m laterum, per diagonales resolvi queat", unfortunately I do not speak Latin (but Google does!!). Any ideas on how to resolve??? I have put in reference to this at beginning of article Bbloodaxe (talk) 19:55, 17 January 2014 (UTC) bbloodaxe

References

1. http://www.math.miami.edu/~armstrong/RCC_AIM.pdf