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In [[mathematics]], a [[polynomial sequence]] <math>\{p_n(z) \}</math> has a '''generalized Appell representation''' if the [[generating function]] for the [[polynomial]]s takes on a certain form: | |||
:<math>K(z,w) = A(w)\Psi(zg(w)) = \sum_{n=0}^\infty p_n(z) w^n | |||
</math> | |||
where the generating function or [[kernel (category theory)|kernel]] <math>K(z,w)</math> is composed of the series | |||
:<math>A(w)= \sum_{n=0}^\infty a_n w^n \quad</math> with <math>a_0 \ne 0 </math> | |||
and | |||
:<math>\Psi(t)= \sum_{n=0}^\infty \Psi_n t^n \quad</math> and all <math>\Psi_n \ne 0 </math> | |||
and | |||
:<math>g(w)= \sum_{n=1}^\infty g_n w^n \quad</math> with <math>g_1 \ne 0.</math> | |||
Given the above, it is not hard to show that <math>p_n(z)</math> is a [[Degree of a polynomial|polynomial of degree]] <math>n</math>. | |||
[[Boas–Buck polynomials]] are a slightly more general class of polynomials. | |||
==Special cases== | |||
* The choice of <math>g(w)=w</math> gives the class of [[Brenke polynomials]]. | |||
* The choice of <math>\Psi(t)=e^t</math> results in the [[Sheffer sequence]] of polynomials, which include the [[general difference polynomials]], such as the [[Newton polynomials]]. | |||
* The combined choice of <math>g(w)=w</math> and <math>\Psi(t)=e^t</math> gives the [[Appell sequence]] of polynomials. | |||
==Explicit representation== | |||
The generalized Appell polynomials have the explicit representation | |||
:<math>p_n(z) = \sum_{k=0}^n z^k \Psi_k h_k.</math> | |||
The constant is | |||
:<math>h_k=\sum_{P} a_{j_0} g_{j_1} g_{j_2} \cdots g_{j_k} </math> | |||
where this sum extends over all [[partition (number theory)|partitions]] of <math>n</math> into <math>k+1</math> parts; that is, the sum extends over all <math>\{j\}</math> such that | |||
:<math>j_0+j_1+ \cdots +j_k = n.\,</math> | |||
For the Appell polynomials, this becomes the formula | |||
:<math>p_n(z) = \sum_{k=0}^n \frac {a_{n-k} z^k} {k!}.</math> | |||
==Recursion relation== | |||
Equivalently, a necessary and sufficient condition that the kernel <math>K(z,w)</math> can be written as <math>A(w)\Psi(zg(w))</math> with <math>g_1=1</math> is that | |||
:<math>\frac{\partial K(z,w)}{\partial w} = | |||
c(w) K(z,w)+\frac{zb(w)}{w} \frac{\partial K(z,w)}{\partial z}</math> | |||
where <math>b(w)</math> and <math>c(w)</math> have the power series | |||
:<math>b(w) = \frac{w}{g(w)} \frac {d}{dw} g(w) | |||
= 1 + \sum_{n=1}^\infty b_n w^n</math> | |||
and | |||
:<math>c(w) = \frac{1}{A(w)} \frac {d}{dw} A(w) | |||
= \sum_{n=0}^\infty c_n w^n.</math> | |||
Substituting | |||
:<math>K(z,w)= \sum_{n=0}^\infty p_n(z) w^n</math> | |||
immediately gives the [[recursion relation]] | |||
:<math> z^{n+1} \frac {d}{dz} \left[ \frac{p_n(z)}{z^n} \right]= | |||
-\sum_{k=0}^{n-1} c_{n-k-1} p_k(z) | |||
-z \sum_{k=1}^{n-1} b_{n-k} \frac{d}{dz} p_k(z). | |||
</math> | |||
For the special case of the Brenke polynomials, one has <math>g(w)=w</math> and thus all of the <math>b_n=0</math>, simplifying the recursion relation significantly. | |||
==See also== | |||
{{portal|Mathematics}} | |||
* [[q-difference polynomial]]s | |||
==References== | |||
* Ralph P. Boas, Jr. and R. Creighton Buck, ''Polynomial Expansions of Analytic Functions (Second Printing Corrected)'', (1964) Academic Press Inc., Publishers New York, Springer-Verlag, Berlin. Library of Congress Card Number 63-23263. | |||
* William C. Brenke, ''On generating functions of polynomial systems'', (1945) American Mathematical Monthly, '''52''' pp. 297–301. | |||
* W. N. Huff, ''The type of the polynomials generated by f(xt) φ(t)'' (1947) Duke Mathematical Journal, '''14''' pp. 1091–1104. | |||
[[Category:Polynomials]] |
Latest revision as of 01:22, 16 January 2014
In mathematics, a polynomial sequence has a generalized Appell representation if the generating function for the polynomials takes on a certain form:
where the generating function or kernel is composed of the series
and
and
Given the above, it is not hard to show that is a polynomial of degree .
Boas–Buck polynomials are a slightly more general class of polynomials.
Special cases
- The choice of gives the class of Brenke polynomials.
- The choice of results in the Sheffer sequence of polynomials, which include the general difference polynomials, such as the Newton polynomials.
- The combined choice of and gives the Appell sequence of polynomials.
Explicit representation
The generalized Appell polynomials have the explicit representation
The constant is
where this sum extends over all partitions of into parts; that is, the sum extends over all such that
For the Appell polynomials, this becomes the formula
Recursion relation
Equivalently, a necessary and sufficient condition that the kernel can be written as with is that
where and have the power series
and
Substituting
immediately gives the recursion relation
For the special case of the Brenke polynomials, one has and thus all of the , simplifying the recursion relation significantly.
See also
Sportspersons Hyslop from Nicolet, usually spends time with pastimes for example martial arts, property developers condominium in singapore singapore and hot rods. Maintains a trip site and has lots to write about after touring Gulf of Porto: Calanche of Piana.
References
- Ralph P. Boas, Jr. and R. Creighton Buck, Polynomial Expansions of Analytic Functions (Second Printing Corrected), (1964) Academic Press Inc., Publishers New York, Springer-Verlag, Berlin. Library of Congress Card Number 63-23263.
- William C. Brenke, On generating functions of polynomial systems, (1945) American Mathematical Monthly, 52 pp. 297–301.
- W. N. Huff, The type of the polynomials generated by f(xt) φ(t) (1947) Duke Mathematical Journal, 14 pp. 1091–1104.