SPECIAL FUNCTIONS
second solution to (18.147) as a linear combination of (18.148) and (18.149) given
by
U(a, c;x)≡π
sinπc[
M(a, c;x)
Γ(a−c+1)Γ(c)−x^1 −cM(a−c+1, 2 −c;x)
Γ(a)Γ(2−c)]
.This has a well behaved limit ascapproaches an integer.
18.11.1 Properties of confluent hypergeometric functionsThe properties of confluent hypergeometric functions can be derived from those
of ordinary hypergeometric functions by lettingx→x/band taking the limit
b→∞, in the same way as both the equation and its solution were derived. A
general procedure of this sort is called aconfluenceprocess.
Special casesThe general nature of the confluent hypergeometric equation allows one to write
a large number of elementary functions in terms of the confluent hypergeometric
functionsM(a, c;x). Once again, such identifications can be made from the series
expansion (18.148) directly, or by transformation of the confluent hypergeometric
equation into a more familiar equation for which the solutions are already
known. Some particular examples of well known special cases of the confluent
hypergeometric function are as follows:
M(a, a;x)=ex, M(1,2; 2x)=exsinhx
x,M(−n,1;x)=Ln(x), M(−n, m+1;x)=n!m!
(n+m)!Lmn(x),M(−n,^12 ;x^2 )=(−1)nn!
(2n)!H 2 n(x), M(−n,^32 ;x^2 ),=(−1)nn!
2(2n+1)!H 2 n+1(x)
x,M(ν+^12 , 2 ν+1;2ix)=ν!eix(x
2)−νJν(x), M(^12 ,^32 ;−x^2 )=√
π
2 xerf(x),wherenandmare integers,Lmn(x) is an associated Legendre polynomial,Hn(x)is
a Hermite polynomial,Jν(x) is a Bessel function and erf(x) is the error function
discussed in section 18.12.4.
Integral representationUsing the integral representation (18.144) of the ordinary hypergeometric func-
tion, exchangingaandband carrying out the process of confluence gives
M(a, c, x)=Γ(c)
Γ(a)Γ(c−a)∫ 10etxta−^1 (1−t)c−a−^1 dt,
(18.150)