Fuss–Catalan number

In combinatorial mathematics and statistics, the Fuss–Catalan numbers are numbers of the form

A_{m}(p,r)\equiv {\frac {r}{mp+r}}{\binom {mp+r}{m}}={\frac {r}{m!}}\prod _{i=1}^{m-1}(mp+r-i)=r{\frac {\Gamma (mp+r)}{\Gamma (1+m)\Gamma (m(p-1)+r+1)}}.

They are named after N. I. Fuss and Eugène Charles Catalan.

In some publications this equation is sometimes referred to as Two-parameter Fuss–Catalan numbers or Raney numbers. The implication is the single-parameter Fuss-Catalan numbers are when $r$ =1 and $p$ =2.

Uses

The Fuss-Catalan represents the number of legal permutations or allowed ways of arranging a number of articles, that is restricted in some way. This means that they are related to the Binomial Coefficient. The key difference between Fuss-Catalan and the Binomial Coefficient is that there are no "illegal" arrangement permutations within Binomial Coefficient, but there are within Fuss-Catalan. An examples of legal and illegal permutations can be better demonstrated by a specific problem such as balanced brackets (see Dyck language).

A general problem is to count the number of balanced brackets (or legal permutations) that a string of 2m brackets forms. By legally arranged, the following rules apply:

For the sequence as a whole, the number of open brackets must equal the number of closed brackets
Working along the sequence, the difference between the number of open and closed brackets cannot be negative

As an numeric example how many combinations can 6 brackets be legally arranged? From the Binomial interpretation there are ${\tbinom {2m}{m}}$ or numerically ${\tbinom {6}{3}}$ = 20 ways of arranging 3 open and 3 closed brackets. However, there are fewer legal combinations than these when all of the above restrictions apply. Evaluating these by hand, there are 5 legal combinations, namely: ()()(); (())(); ()(()); (()()); ((())). This corresponds to the Fuss-Catalan formula when p=2, r=1 which is the Catalan number formula ${\tfrac {1}{2m+1}}{\tbinom {2m}{m}}$ or ${\tfrac {1}{4}}{\tbinom {6}{3}}$ =5. By simple subtraction, there are ${\tfrac {m}{m+1}}{\tbinom {2m}{m}}$ or ${\tfrac {3}{4}}{\tbinom {6}{3}}$ =15 illegal combinations. To further illustrate the subtlety of the problem, if one were to persist with solving the problem just using the Binomial formula, it would be realised that the 2 rules imply that the sequence must start with an open bracket and finish with a closed bracket. This implies that there are ${\tbinom {2m-2}{m-1}}$ or ${\tbinom {4}{2}}$ =6 combinations. This is inconsistent with the above answer of 5, and the missing combination is: ())((), which is illegal and would complete the binomial interpretation.

Whilst the above is a concrete example Catalan numbers, similar problems can be evaluated using Fuss-Catalan formula:

Computer Stack: ways of arranging and completing a computer stack of instructions, each time step 1 instruction is processed and p new instructions arrive randomly. If at the beginning of the sequence there are r instructions outstanding.
Betting: ways of losing all money when betting. A player has a total stake pot that allows them to make r bets, and plays a game of chance that pays p times the bet stake.
Tries: Calculating the number of order m tries on n nodes.^[1]

Special Cases

A_{0}(p,r)=1

;

A_{1}(p,r)=r

;

A_{2}(p,1)=p

If $p=0$ , we recover the Binomial coefficients $A_{m}(0,r){=}{\binom {r}{m}}$

A_{m}(0,1)=1,1

;

A_{m}(0,2)=1,2,1

;

A_{m}(0,3)=1,3,3,1

;

A_{m}(0,4)=1,4,6,4,1

If $p=1$ , Pascal's Triangle appears, read along diagonals:

A_{m}(1,1)=1,1,1,1,1,1,1,1,1,1,\ldots

;

A_{m}(1,2)=1,2,3,4,5,6,7,8,9,10,\ldots

;

A_{m}(1,3)=1,3,6,10,15,21,28,35,45,55,\ldots

;

A_{m}(1,4)=1,4,10,20,35,56,84,120,165,220,\ldots

;

A_{m}(1,5)=1,5,15,35,70,126,210,330,495,715,\ldots

;

A_{m}(1,6)=1,6,21,56,126,252,462,792,1287,2002,\ldots

Examples

For subindex $m\geq 0$ the numbers are:

Examples with $p=2$ :

A_{m}(2,1)=1,1,2,5,14,42,132,429,1430,4862,\ldots

A000108, known as the Catalan Numbers

A_{m}(2,2)=1,2,5,14,42,132,429,1430,4862,16796,\ldots =A_{m+1}(2,1)

A_{m}(2,3)=1,3,9,28,90,297,1001,3432,11934,41990,\ldots

A000245

A_{m}(2,4)=1,4,14,48,165,572,2002,7072,25194,90440,\ldots

A002057

Examples with $p=3$ :

A_{m}(3,1)=1,1,3,12,55,273,1428,7752,43263,246675,\ldots

A001764

A_{m}(3,2)=1,2,7,30,143,728,3876,21318,120175,690690,\ldots

A006013

A_{m}(3,3)=1,3,12,55,273,1428,7752,43263,246675,1430715,\ldots =A_{m+1}(3,1)

A_{m}(3,4)=1,4,18,88,455,2448,13566,76912,444015,2601300,\ldots

A006629

Examples with $p=4$ :

A_{m}(4,1)=1,1,4,22,140,969,7084,53820,420732,3362260,\ldots

A002293

A_{m}(4,2)=1,2,9,52,340,2394,17710,135720,1068012,8579560,\ldots

A069271

A_{m}(4,3)=1,3,15,91,612,4389,32890,254475,2017356,16301164,\ldots

A006632

A_{m}(4,4)=1,4,22,140,969,7084,53820,420732,3362260,27343888,\ldots =A_{m+1}(4,1)

Algebra

Recurrence

A_{m}(p,r)=A_{m}(p,r-1)+A_{m-1}(p,p+r-1)

equation (1)

This means in particular that from

A_{m}(p,0)=0

equation (2)

and

A_{0}(p,r)=1

equation (3)

one can generate all other Fuss–Catalan numbers if $p$ is an integer.

Riordan (see references) obtains a convolution type of recurrence:

A_{m}(p,s+r)=\sum _{k=0}^{m}A_{k}(p,r)A_{m-k}(p,s)

equation(4)

Generating Function

Paraphrasing the Densities of the Raney distributions ^[2] paper, let the ordinary generating function with respect to the index $m$ be defined as follows:

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

equation (5).

Looking at equations (1) and (2), when $r$ =1 it follows that

A_{m}(p,p)=A_{m+1}(p,1)

equation (6).

Also note this result can be derived by similar substitutions into the other formulas representation, such as the Gamma ratio representation at the top of this article. Using (6) and substituting into (5) an equivalent representation expressed as a generating function can be formulated as

B_{p,1}(z)=1+zB_{p,p}(z)

Finally, extending this result by using Lambert's equivalence

B_{p,1}(z)^{r}=B_{p,r}(z)

The following result can be derived for the ordinary generating function for all the Fuss-Catalan sequences.

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

Recursion Representation

Recursion forms of this are as follows: The most obvious form is:

A_{m}(p,r)={\frac {m-1}{m}}{\frac {\binom {mp+r-1}{m-1}}{\binom {(m-1)p+r-1}{m-2}}}A_{m-1}(p,r)

Also, a less obvious form is

A_{m}(p,r)={\frac {(m-1)p+r}{m}}{\frac {\binom {mp+r-1}{p-1}}{\binom {m(p-1)+r}{p-1}}}A_{m-1}(p,r)

Alternate Representations

In some problems it is easier to use different formula configurations or variations. Below are a two examples using just the binomial function:

A_{m}(p,r)\equiv {\frac {r}{mp+r}}{\binom {mp+r}{m}}={\frac {r}{m(p-1)+r}}{\binom {mp+r-1}{m}}={\frac {r}{m}}{\binom {mp+r-1}{m-1}}

These variants can be converted into product, Gamma or Factorial representations too.

References

↑ Clark, David (1996). "Compact Tries". Compact Pat Trees (Thesis). p. 34.
↑ Mlotkowski, Wojciech; Penson, Karol A.; Zyczkowski, Karol (2013). "Densities of the Raney distributions". Docum. Mathm. 18: 1593–1596. arXiv:1211.7259.

Fuss, N. I. (1791). "Solutio quaestionis, quot modis polygonum n laterum in polygona m laterum, per diagonales resolvi queat". Nova Acta Academiae Sci. Petropolitanae. 9: 243–251.
Riordan, J. (1968). Combinatorial identities. Wiley. ISBN 978-0471722755.
Bisch, Dietmar; Jones, Vaughan (1997). "Algebras associated to intermediate subfactors". Invent. Mathem. 128 (1): 89–157. Bibcode:1997InMat.128...89J. doi:10.1007/s002220050137.
Przytycki, Jozef H.; Sikora, Adam S. (2000). "Polygon dissections and Euler, Fuss, Kirkman , and Cayley Numbers". J. Combinat. Theory A. 92: 68–76. doi:10.1006/jcta.1999.3042.
Aval, Jean-Christophe (2008). "Multivariate Fuss-Catalan numbers". Discr. Math. 20 (308): 4660–4669. doi:10.1016/j.disc.2007.08.100.
Alexeev, N.; Götze, F; Tikhomirov, A. (2010). "Asymptotic distribution of singular values of powers of random matrices". Lith. Math. J. 50 (2): 121–132. doi:10.1007/s10986-010-9074-4.
Mlotkowski, Wojciech (2010). "Fuss-Catalan Numbers in noncommutative probability". Docum. Mathm. 15: 939–955.
Penson, Karol A.; Zyczkowski, Karol (2011). "Product of Ginibre matrices: Fuss-Catalan and Raney distributions". Phys. Rev. E. 83: 061118. arXiv:1103.3453. Bibcode:2011PhRvE..83f1118P. doi:10.1103/PhysRevE.83.061118.
Gordon, Ian G.; Griffeth, Stephen (2012). "Catalan numbers for complex reflection groups". Am. J. Math. 134 (6): 1491–1502. doi:10.1353/ajm.2012.0047.
Mlotkowski, W.; Penson, K. A. (2015). "A Fuss-type family of positive definite sequences". arXiv:1507.07312.

Classes of natural numbers

Powers and
related numbers

Of the form
a × 2^b ± 1

Other polynomial
numbers

Recursively defined
numbers

Possessing a
specific set
of other numbers

Expressible via
specific sums

Generated
via a sieve

Lucky

Code related

Meertens

Figurate numbers

2-dimensional

centered	Centered triangular Centered square Centered pentagonal Centered hexagonal Centered heptagonal Centered octagonal Centered nonagonal Centered decagonal Star

non-centered	Triangular Square Square triangular Pentagonal Hexagonal Heptagonal Octagonal Nonagonal Decagonal Dodecagonal

3-dimensional

centered	Centered tetrahedral Centered cube Centered octahedral Centered dodecahedral Centered icosahedral

non-centered	Tetrahedral Octahedral Dodecahedral Icosahedral Stella octangula

pyramidal	Square pyramidal Pentagonal pyramidal Hexagonal pyramidal Heptagonal pyramidal

4-dimensional

centered	Centered pentachoric Squared triangular

non-centered	Pentatope

Pseudoprimes

Combinatorial
numbers

Arithmetic functions

By properties of σ(n)	Abundant Almost perfect Arithmetic Colossally abundant Descartes Hemiperfect Highly abundant Highly composite Hyperperfect Multiply perfect Perfect Practical number Primitive abundant Quasiperfect Refactorable Sublime Superabundant Superior highly composite Superperfect

By properties of Ω(n)	Almost prime Semiprime

By properties of φ(n)	Highly cototient Highly totient Noncototient Nontotient Perfect totient Sparsely totient

By properties of s(n)	Amicable Betrothed Deficient Semiperfect

Dividing a quotient

Other prime factor
or divisor related
numbers

Recreational
mathematics

Base-dependent
numbers

This article is issued from Wikipedia - version of the 9/22/2016. The text is available under the Creative Commons Attribution/Share Alike but additional terms may apply for the media files.