In mathematics, a bilateral hypergeometric series is a series Σan summed over all integers n, and such that the ratio
an/an+1
of two terms is a rational function of n. The definition of the generalized hypergeometric series is similar, except that the terms with negative n must vanish; the bilateral series will in general have infinite numbers of non-zero terms for both positive and negative n.
The bilateral hypergeometric series fails to converge for most rational functions, though it can be analytically continued to a function defined for most rational functions. There are several summation formulas giving its values for special values where it does converge.
The bilateral hypergeometric series pHp is defined by
{}pHp(a1,\ldots,ap;b1,\ldots,bp;z)= {}pHp\left(\begin{matrix}a1&\ldots&ap\\b1&\ldots&bp\ \end{matrix};z\right)= \sum
| ||||
| n=-infty |
zn
where
(a)n=a(a+1)(a+2) … (a+n-1)
is the rising factorial or Pochhammer symbol.
Usually the variable z is taken to be 1, in which case it is omitted from the notation.It is possible to define the series pHq with different p and q in a similar way, but this either fails to converge or can be reduced to the usual hypergeometric series by changes of variables.
Suppose that none of the variables a or b are integers, so that all the terms of the series are finite and non-zero. Then the terms with n<0 diverge if |z| <1, and the terms with n>0 diverge if |z| >1, so the series cannot converge unless |z|=1. When |z|=1, the series converges if
\Re(b1+ … bn-a1- … -an)>1.
The bilateral hypergeometric series can be analytically continued to a multivalued meromorphic function of several variables whose singularities arebranch points at z = 0 and z=1 and simple poles at ai = -1, -2,... and bi = 0, 1, 2, ...This can be done as follows. Suppose that none of the a or b variables are integers. The terms with n positive converge for |z| <1 to a function satisfying an inhomogeneous linear equation with singularities at z = 0 and z=1, so can be continued to a multivalued function with these points as branch points. Similarly the terms with n negative converge for |z| >1 to a function satisfying an inhomogeneous linear equation with singularities at z = 0 and z=1, so can also be continued to a multivalued function with these points as branch points. The sum of these functions gives the analytic continuation of the bilateral hypergeometric series to all values of z other than 0 and 1, and satisfies a linear differential equation in z similar to the hypergeometric differential equation.
{}2H2(a,b;c,d;1)=
| ||||
| \sum | ||||
| n=-infty |
=
| \Gamma(d)\Gamma(c)\Gamma(1-a)\Gamma(1-b)\Gamma(c+d-a-b-1) | |
| \Gamma(c-a)\Gamma(c-b)\Gamma(d-a)\Gamma(d-b) |
This is sometimes written in the equivalent form
| ||||
| \sum | ||||
| n=-infty |
=
| \pi2 | |
| \sin(\pia)\sin(\pib) |
| \Gamma(c+d-a-b-1) | |
| \Gamma(c-a)\Gamma(d-a)\Gamma(c-b)\Gamma(d-b) |
.
gave the following generalization of Dougall's formula:
{}3H3(a,b,f+1;d,e,f;1)=
| ||||
| \sum | ||||
| n=-infty |
=λ
| \Gamma(d)\Gamma(e)\Gamma(1-a)\Gamma(1-b)\Gamma(d+e-a-b-2) | |
| \Gamma(d-a)\Gamma(d-b)\Gamma(e-a)\Gamma(e-b) |
λ=f-1\left[(f-a)(f-b)-(1+f-d)(1+f-e)\right].