In mathematics, the Neumann polynomials, introduced by Carl Neumann for the special case

\alpha=0

, are a sequence of polynomials in

1/t

used to expand functions in term of

Bessel function Bessel functions, first defined by the mathematician Daniel Bernoulli and then generalized by Friedrich Bessel, are canonical solutions of Bessel's differential equation x^2 \frac + x \frac + \left(x^2 - \alpha^2 \right)y = 0 for an arbitrar ...

s. The first few polynomials are :

O_0^(t)=\frac 1 t,

O_1^(t)=2\frac ,

O_2^(t)=\frac + 4\frac ,

O_3^(t)=2\frac + 8\frac ,

O_4^(t)=\frac + 4\frac + 16\frac .

A general form for the polynomial is :

O_n^(t)= \frac \sum_^ (-1)^\frac   \left(\frac 2 t \right)^,

and they have the "generating function" :

\frac  \frac 1 = \sum_O_n^(t) J_(z),

where ''J'' are

s. To expand a function ''f'' in the form :

f(z)=\sum_ a_n J_(z)\,

for

, z,, compute
: a_n=\frac 1  \oint_ \fracf(z) O_n^(z)\,dz, where c' and ''c'' is the distance of the nearest singularity of z^ f(z) from z=0 .

Examples

An example is the extension :

\left(\tfracz\right)^s= \Gamma(s)\cdot\sum_(-1)^k J_(z)(s+2k),

or the more general Sonine formula II.7.10.1, p.64 :

e^= \Gamma(s)\cdot\sum_i^k C_k^(\gamma)(s+k)\frac.

where

C_k^

is Gegenbauer's polynomial. Then, :

\fracJ_s(z)= \sum_(-1)^(s+2i)J_(z),

\sum_ t^n J_(z)= \frac \sum_\frac\frac= \int_0^\infty e^\frac  \frac\,dx,

the confluent hypergeometric function :

M(a,s,z)= \Gamma (s) \sum_^\infty \left(-\frac\right)^k L_k^(t) \frac,

and in particular :

\frac= \frace^\sum_L_k^\left(\frac4\right)(4 i z)^k \frac,

the index shift formula :

\Gamma(\nu-\mu) J_\nu(z)= \Gamma(\mu+1) \sum_\frac \left(\frac z 2\right)^J_(z),

the Taylor expansion (addition formula) :

\frac= \sum_\frac\frac,

(cf.) and the expansion of the integral of the Bessel function, :

\int J_s(z)dz= 2 \sum_ J_{s+2k+1}(z),

are of the same type.

Notes

Polynomials Special functions

Examples

See also

Notes