All functions in this subsection and §15.8(ii) assume their principal values.
| 15.8.1 | |||
| . | |||
|
ⓘ
| |||
With , polynomial cases of (15.8.2)–(15.8.5) are given by
| 15.8.6 | ||||
|
ⓘ
| ||||
| 15.8.7 | ||||
|
ⓘ
| ||||
with the understanding that if , , then .
If is a nonnegative integer, then
| 15.8.8 | |||
| , | |||
|
ⓘ
| |||
| 15.8.9 | |||
| . | |||
|
ⓘ
| |||
In (15.8.8) when is a nonpositive integer is interpreted as . Also, if is a nonpositive integer, then (15.8.6) applies.
Alternatively, if is a negative integer, then we interchange and in .
If is a nonnegative integer, then
| 15.8.10 | |||
| , | |||
|
ⓘ
| |||
| 15.8.11 | |||
| . | |||
|
ⓘ
| |||
In (15.8.11) when is a nonpositive integer, is interpreted as . Also, if or or both are nonpositive integers, then (15.8.7) applies.
Lastly, if is a negative integer, then we first apply the transformation
| 15.8.12 | |||
| . | |||
|
ⓘ
| |||
A quadratic transformation relates two hypergeometric functions, with the variable in one a quadratic function of the variable in the other, possibly combined with a fractional linear transformation.
A necessary and sufficient condition that there exists a quadratic transformation is that at least one of the equations shown in Table 15.8.1 is satisfied.
| Group 1 | Group 2 | Group 3 | Group 4 |
|---|---|---|---|
The hypergeometric functions that correspond to Groups 1 and 2 have as variable. The hypergeometric functions that correspond to Groups 3 and 4 have a nonlinear function of as variable. The transformation formulas between two hypergeometric functions in Group 2, or two hypergeometric functions in Group 3, are the linear transformations (15.8.1).
In the equations that follow in this subsection all functions take their principal values.
| 15.8.13 | ||||
| , | ||||
|
ⓘ
| ||||
| 15.8.14 | ||||
| . | ||||
|
ⓘ
| ||||
| 15.8.15 | ||||
| , | ||||
|
ⓘ
| ||||
| 15.8.16 | ||||
| . | ||||
|
ⓘ
| ||||
| 15.8.17 | ||||
| , | ||||
|
ⓘ
| ||||
| 15.8.18 | ||||
| . | ||||
|
ⓘ
| ||||
| 15.8.19 | ||||
| , | ||||
|
ⓘ
| ||||
| 15.8.20 | ||||
| . | ||||
|
ⓘ
| ||||
| 15.8.21 | ||||
| , . | ||||
|
ⓘ
| ||||
| 15.8.22 | ||||
| , . | ||||
|
ⓘ
| ||||
| 15.8.23 | |||
| , . | |||
|
ⓘ
| |||
| 15.8.24 | |||
| . | |||
|
ⓘ
| |||
| 15.8.25 | |||
| , . | |||
|
ⓘ
| |||
| 15.8.26 | |||
| , . | |||
|
ⓘ
| |||
| 15.8.27 | |||
| , . | |||
|
ⓘ
| |||
| 15.8.28 | |||
| , . | |||
|
ⓘ
| |||
When the intersection of two groups in Table 15.8.1 is not empty there exist special quadratic transformations, with only one free parameter, between two hypergeometric functions in the same group.
, in Groups 1 and 2.
(15.8.21) becomes
| 15.8.29 | |||
|
ⓘ
| |||
This is a quadratic transformation between two cases in Group 1.
We can also use (15.8.13), followed by the inverse of (15.8.15), and obtain
| 15.8.30 | |||
|
ⓘ
| |||
which is a quadratic transformation between two cases in Group 3.
For further examples see Andrews et al. (1999, pp. 130–132 and 176–177).
| 15.8.31 | |||
| . | |||
|
ⓘ
| |||
With
| 15.8.32 | |||
| , . | |||
|
ⓘ
| |||
| 15.8.33 | |||
|
ⓘ
| |||
provided that lies in the intersection of the open disks , or equivalently, . This is used in a cubic analog of the arithmetic-geometric mean. See Borwein and Borwein (1991), and also Berndt et al. (1995).