classical orthogonal polynomials

… ►

§18.9(i) Recurrence Relations

… ►

► ►►

$p_n(x)$	$A_n$	$B_n$	$C_n$
…

►

… ►

► ►►

$p_n(x)$	$a_n$	$b_n$	$c_n$
…

►

… ►

§18.9(ii) Contiguous Relations in the Parameters and the Degree

… ►

§18.9(iii) Derivatives

…

… ►

► ►►

#	$f(x)$	$A(x)$	$B(x)$	$C(x)$	${\lambda }_n$
…

►

…

… ► … ►

Classical OP’s

…

§18.17 Integrals

… ►

§18.17(v) Fourier Transforms

… ►

§18.17(vi) Laplace Transforms

… ►

§18.17(vii) Mellin Transforms

… ►

§18.17(ix) Compendia

…

§18.10 Integral Representations

… ►See also §18.17.

… ►His well-known book Classical and Quantum Orthogonal Polynomials in One Variable was published by Cambridge University Press in 2005 and reprinted with corrections in paperback in Ismail (2009). …

§18.37 Classical OP’s in Two or More Variables

…

… ►For applications in which the OP’s appear only as terms in series expansions (compare §18.18(i)) the need to compute them can be avoided altogether by use instead of Clenshaw’s algorithm (§3.11(ii)) and its straightforward generalization to OP’s other than Chebyshev. …

… ►

§18.11(ii) Formulas of Mehler–Heine Type

…

… ►The classical orthogonal polynomials are defined with: … ►

§18.2(vi) Zeros

… ► …