Equations (24.5.3) and (24.5.4) enable and to be computed by recurrence. For higher values of more efficient methods are available. For example, the tangent numbers can be generated by simple recurrence relations obtained from (24.15.3), then (24.15.4) is applied. A similar method can be used for the Euler numbers based on (4.19.5). For details see Knuth and Buckholtz (1967).
Another method is based on the identities
| 24.19.1 | |||
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If denotes the right-hand side of (24.19.1) but with the second product taken only for , then for . For proofs and further information see Fillebrown (1992).
For number-theoretic applications it is important to compute for ; in particular to find the irregular pairs for which . We list here three methods, arranged in increasing order of efficiency.
Tanner and Wagstaff (1987) derives a congruence for Bernoulli numbers in terms of sums of powers. See also §24.10(iii).
Buhler et al. (1992) uses the expansion
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and computes inverses modulo of the left-hand side. Multisectioning techniques are applied in implementations. See also Crandall (1996, pp. 116–120).