Charlier polynomial

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The Charlier polynomials are $$C_n(x;\mu)={}_2F_0 \left(-n,-x, -\dfrac{1}{\mu} \right) = (-1)^n n! L_n^{(-1-x)} \left( - \dfrac{1}{\mu} \right),$$ where ${}_2F_1$ denotes the hypergeometric pFq and $L_n^{(\alpha)}$ denotes the associated Laguerre polynomials.

Properties

Theorem: The Charlier polynomials are orthogonal polynomials with respect to the inner product $$\langle C_n(\cdot;\mu), C_m(\cdot;\mu) \rangle = \displaystyle\sum_{k=0}^{\infty} \dfrac{\mu^k}{k!} C_n(k;\mu)C_m(k;\mu).$$

Proof:

Theorem

The following formula holds: $$\displaystyle\lim_{\beta \rightarrow \infty} M_n \left(x;\beta,\dfrac{a}{\beta+a} \right) = C_n(x;a),$$ where $M_n$ denotes a Meixner polynomial and $C_n$ denotes a Charlier polynomial.

Proof

References

Orthogonal polynomials
Associatedlaguerrelthumb.png
Laguerre $L_n^{(\alpha)}$
Batemanpolynomialthumb.png
Bateman $F_n$
Bernoullibthumb.png
Bernoulli $B$
Besselpolynomialsthumb.png
Bessel poly
Chebyshevtthumb.png
Chebyshev T
Chebyshevuthumb.png
Chebyshev U
Dicksonthumb.png
Dickson
Eulerethumb.png
Euler $E$
Gegenbauercthumb.png
Gegenbauer $C$
Hermitephysthumb.png
Hermite (phys)
Hermiteprobthumb.png
Hermite (prob)
Jacobipthumb.png
Jacobi $P^{(\alpha,\beta)}$
Laguerrelthumb.png
Laguerre $L$
Legendrepthumb.png
Legendre $P$
Bernoullibthumb.png
Bernoulli $B$
Chebyshevtthumb.png
Chebyshev $T$
Fibonaccithumb.png
Fibonacci
Lucasthumb.png
Lucas
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