In mathematics, the Askey scheme is a way of organizing

orthogonal polynomials In mathematics, an orthogonal polynomial sequence is a family of polynomials such that any two different polynomials in the sequence are orthogonal to each other under some inner product. The most widely used orthogonal polynomials are the cl ...

of hypergeometric or basic hypergeometric type into a hierarchy. For the classical orthogonal polynomials discussed in , the Askey scheme was first drawn by and by , and has since been extended by and to cover basic orthogonal polynomials.

Askey scheme for hypergeometric orthogonal polynomials

give the following version of the Askey scheme: ;

_4F_3(4)

: Wilson , Racah ;

_3F_2(3)

: Continuous dual Hahn , Continuous Hahn , Hahn , dual Hahn ;

_2F_1(2)

: Meixner–Pollaczek , Jacobi , Pseudo Jacobi , Meixner , Krawtchouk ;

_2F_0(1)\ \ / \ \ _1F_1(1)

: Laguerre , Bessel , Charlier ;

_2F_0(0)

: Hermite Here

_pF_q(n)

indicates a hypergeometric series representation with

n

parameters

Askey scheme for basic hypergeometric orthogonal polynomials

give the following scheme for basic hypergeometric orthogonal polynomials: ;₄

\phi

₃: Askey–Wilson , q-Racah ;₃

\phi

₂: Continuous dual q-Hahn , Continuous q-Hahn , Big q-Jacobi , q-Hahn , dual q-Hahn ;₂

\phi

₁: Al-Salam–Chihara , q-Meixner–Pollaczek , Continuous q-Jacobi , Big q-Laguerre , Little q-Jacobi , q-Meixner , Quantum q-Krawtchouk , q-Krawtchouk , Affine q-Krawtchouk , Dual q-Krawtchouk ;₂

\phi

₀/₁

\phi

₁: Continuous big q-Hermite , Continuous q-Laguerre , Little q-Laguerre , q-Laguerre , q-Bessel , q-Charlier , Al-Salam–Carlitz I , Al-Salam–Carlitz II ;₁

\phi

₀: Continuous q-Hermite , Stieltjes–Wigert , Discrete q-Hermite I , Discrete q-Hermite II

Completeness

While there are several approaches to constructing still more general families of orthogonal polynomials, it is usually not possible to extend the Askey scheme by reusing hypergeometric functions of the same form. For instance, one might naively hope to find new examples given by :

p_n(x) = _F_q \left ( \begin -n, n + \mu, a_1(x), \dots, a_(x) \\ b_1, \dots, b_q \end ; 1 \right )

above

q = 3

which corresponds to the Wilson polynomials. This was ruled out in under the assumption that the

a_i(x)

are degree 1 polynomials such that :

\prod_^ (a_i(x) + r) = \prod_^ a_i(x) + \pi(r)

for some polynomial

\pi(r)

References

* * * * * * *{{Citation , last1=Labelle , first1=Jacques , editor1-last=Brezinski , editor1-first=C. , editor2-last=Draux , editor2-first=A. , editor3-last=Magnus , editor3-first=Alphonse P. , editor4-last=Maroni , editor4-first=Pascal , editor5-last=Ronveaux , editor5-first=A. , title=Polynômes Orthogonaux et Applications. Proceedings of the Laguerre Symposium held at Bar-le-Duc , publisher=

Springer-Verlag Springer Science+Business Media, commonly known as Springer, is a German multinational publishing company of books, e-books and peer-reviewed journals in science, humanities, technical and medical (STM) publishing. Originally founded in 1842 ...

, location=Berlin, New York , series=Lecture Notes in Math. , isbn=978-3-540-16059-5 , doi=10.1007/BFb0076527 , mr=838967 , year=1985 , volume=1171 , chapter=Tableau d'Askey , pages=xxxvi–xxxvii Orthogonal polynomials Hypergeometric functions Q-analogs