Whittaker functions
The functions $ M _ {\lambda , \mu } ( z) $
and $ W _ {\lambda , \mu } ( z) $
which are solutions of the Whittaker equation
$$ \tag{* } w ^ {\prime\prime} + \left ( \frac{ {1 / 4 } - \mu ^ {2} }{z ^ {2} } + { \frac \lambda {z} } - { \frac{1}{4} } \right ) w = 0. $$
The function $ W _ {\lambda , \mu } $ satisfies the equation
$$ W _ {\lambda , \mu } ( z) = \ \frac{\Gamma (- 2 \mu ) }{\Gamma \left ( { \frac{1}{2} } - \lambda - \mu \right ) } M _ {\lambda , \mu } ( z) + \frac{\Gamma ( 2 \mu ) }{\Gamma \left ( { \frac{1}{2} } - \lambda + \mu \right ) } M _ {\lambda , - \mu } ( z). $$
The pairs of functions $ M _ {\lambda , \mu } ( z) , M _ {\lambda , - \mu } ( z) $ and $ W _ {\lambda , \mu } ( z) , W _ {- \lambda , \mu } ( z) $ are linearly independent solutions of the equation (*). The point $ z = 0 $ is a branching point for $ M _ {\lambda , \mu } ( z) $, and $ z = \infty $ is an essential singularity.
Relation with other functions:
with the degenerate hypergeometric function:
$$ M _ {\lambda , \mu } ( z) = \ z ^ {\mu + 1/2 } e ^ {-} z/2 \Phi \left ( \mu - \lambda + \frac{1}{2} ; \ 2 \mu + 1; z \right ) , $$
with the modified Bessel functions and the Macdonald function:
$$ M _ {0, \mu } ( z) = \ 2 ^ {2 \mu } \Gamma ( \mu + 1) \sqrt z I _ \mu \left ( { \frac{z}{2} } \right ) , $$
$$ W _ {0, \mu } ( z) = \sqrt { \frac{z} \pi } K _ \mu \left ( { \frac{z}{2} } \right ) ; $$
with the probability integral:
$$ W _ {- {1 / 4 } , {1 / 4 } } ( z) = \ 2 z ^ {1/4} e ^ {z/2} \mathop{\rm Erfc} ( \sqrt z ); $$
with the Laguerre polynomials:
$$ W _ {n + \mu + 1/2, \mu } ( z) = \ n! (- 1) ^ {n} z ^ {\mu + 1/2 } e ^ {-} z/2 L _ {n} ^ {2 \mu } ( z). $$
References
[1] | H. Bateman (ed.) A. Erdélyi (ed.) et al. (ed.) , Higher transcendental functions , 2. Bessel functions, parabolic cylinder functions, orthogonal polynomials , McGraw-Hill (1953) |
[2] | E.T. Whittaker, G.N. Watson, "A course of modern analysis" , Cambridge Univ. Press (1952) |
Comments
The Whittaker function $ W _ {\lambda , \mu } $ can be expressed in terms of the $ \Psi $- function introduced in confluent hypergeometric function:
$$ W _ {\lambda , \mu } ( z) = e ^ {- z/2 } z ^ {\mu + 1/2 } \Psi ( \mu - \lambda + 1/2; 2 \mu + 1; z). $$
Thus, the special cases discussed in confluent hypergeometric function can be rewritten as special cases for the Whittaker functions. See also the references given there.
Whittaker functions. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Whittaker_functions&oldid=12501