Leading terms of the power series for and for are:
Leading terms of the of the power series for are:
| 28.6.14 | |||
|
ⓘ
| |||
For more details on these expansions and recurrence relations for the coefficients see Frenkel and Portugal (2001, §2).
The coefficients of the power series of , and also , are the same until the terms in and , respectively. Then
| 28.6.15 | |||
|
ⓘ
| |||
Higher coefficients in the foregoing series can be found by equating coefficients in the following continued-fraction equations:
| 28.6.16 | |||
| , | |||
|
ⓘ
| |||
| 28.6.17 | |||
| , | |||
|
ⓘ
| |||
| 28.6.18 | |||
| , | |||
|
ⓘ
| |||
| 28.6.19 | |||
| . | |||
|
ⓘ
| |||
Numerical values of the radii of convergence of the power series (28.6.1)–(28.6.14) for are given in Table 28.6.1. Here for , for , and for and . (Table 28.6.1 is reproduced from Meixner et al. (1980, §2.4).)
| 0 or 1 | ||||||
|---|---|---|---|---|---|---|
| 2 | ||||||
| 3 | ||||||
| 4 | ||||||
| 5 | ||||||
| 6 | ||||||
| 7 | ||||||
| 8 | ||||||
| 9 | ||||||
It is conjectured that for large , the radii increase in proportion to the square of the eigenvalue number ; see Meixner et al. (1980, §2.4). It is known that
| 28.6.20 | |||
|
ⓘ
| |||
where is the unique root of the equation in the interval , and . For and see §19.2(ii).
Leading terms of the power series for the normalized functions are:
For ,
| 28.6.26 | |||
|
ⓘ
| |||