Difference between revisions of "Charlier polynomials"
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$$ | $$ | ||
| − | j( x) = e ^ {-} | + | j( x) = e ^ {-a} |
\frac{a ^ {x} }{x!} | \frac{a ^ {x} }{x!} | ||
,\ \ | ,\ \ | ||
| Line 28: | Line 28: | ||
P _ {n} ( x; a) = \sqrt { | P _ {n} ( x; a) = \sqrt { | ||
\frac{a ^ {n} }{n!} | \frac{a ^ {n} }{n!} | ||
| − | } \sum _ { k= } | + | } \sum _ { k= 0} ^ { n } (- 1) ^ {n-k} |
\left ( \begin{array}{c} | \left ( \begin{array}{c} | ||
n \\ | n \\ | ||
k | k | ||
\end{array} | \end{array} | ||
| − | \right ) k! a ^ {-} | + | \right ) k! a ^ {-k} \left ( \begin{array}{c} |
x \\ | x \\ | ||
k | k | ||
| Line 42: | Line 42: | ||
$$ | $$ | ||
= \ | = \ | ||
| − | a ^ {n / 2 } ( n!) ^ {- 1 / 2 } [ j( x)] ^ {-} | + | a ^ {n / 2 } ( n!) ^ {- 1 / 2 } [ j( x)] ^ {-1} \Delta ^ {n} j ( x- n). |
$$ | $$ | ||
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$$ | $$ | ||
| − | P _ {n} ( x; a) = \sqrt {n! over {a ^ {n} } } L _ {n} ^ {( | + | P _ {n} ( x; a) = \sqrt {n! \over {a ^ {n} } } L _ {n} ^ {( x- n)} ( a) = \ |
| − | \sqrt {n! over {a ^ {n} } } L _ {n} ( a; x- n). | + | \sqrt {n! \over {a ^ {n} } } L _ {n} ( a; x- n). |
$$ | $$ | ||
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\frac{P _ {n} ( x ; a ) }{P _ {n} ( 0 ; a ) } | \frac{P _ {n} ( x ; a ) }{P _ {n} ( 0 ; a ) } | ||
= \ | = \ | ||
| − | {} _ {2} F _ {0} ( - n , - x ; - a ^ {-} | + | {} _ {2} F _ {0} ( - n , - x ; - a ^ {-1} ) . |
$$ | $$ | ||
Revision as of 18:28, 24 December 2020
Polynomials that are orthogonal on the system of non-negative integer points with an integral weight $ d \sigma ( x) $,
where $ \sigma ( x) $
is a step function with jumps defined by the formula
$$ j( x) = e ^ {-a} \frac{a ^ {x} }{x!} ,\ \ x = 0, 1 \dots \ \ a > 0. $$
The orthonormal Charlier polynomials have the following representations:
$$ P _ {n} ( x; a) = \sqrt { \frac{a ^ {n} }{n!} } \sum _ { k= 0} ^ { n } (- 1) ^ {n-k} \left ( \begin{array}{c} n \\ k \end{array} \right ) k! a ^ {-k} \left ( \begin{array}{c} x \\ k \end{array} \right ) = $$
$$ = \ a ^ {n / 2 } ( n!) ^ {- 1 / 2 } [ j( x)] ^ {-1} \Delta ^ {n} j ( x- n). $$
The Charlier polynomials are connected with the Laguerre polynomials by
$$ P _ {n} ( x; a) = \sqrt {n! \over {a ^ {n} } } L _ {n} ^ {( x- n)} ( a) = \ \sqrt {n! \over {a ^ {n} } } L _ {n} ( a; x- n). $$
Introduced by C. Charlier [1]. Since the function $ j( x) $ defines a Poisson distribution, the polynomials $ \{ P _ {n} ( x; a) \} $ are called Charlier–Poisson polynomials.
References
| [1] | C. Charlier, "Application de la théorie des probabilités à l'astronomie" , Paris (1931) |
| [2] | H. Bateman (ed.) A. Erdélyi (ed.) et al. (ed.) , Higher transcendental functions , 2. Bessel functions, parabolic cylinder functions, orthogonal polynomials , McGraw-Hill (1953) |
| [3] | G. Szegö, "Orthogonal polynomials" , Amer. Math. Soc. (1975) |
Comments
In the formula above, $ \Delta $ denotes taking first differences, i.e. $ \Delta f ( x) = f ( x + 1 ) - f ( x) $. Another common notation and an expression by hypergeometric functions is:
$$ C _ {n} ( x ; a ) = \ \frac{P _ {n} ( x ; a ) }{P _ {n} ( 0 ; a ) } = \ {} _ {2} F _ {0} ( - n , - x ; - a ^ {-1} ) . $$
Charlier polynomials. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Charlier_polynomials&oldid=46325