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11: 9.17 Methods of Computation
However, in the case of Ai ( z ) and Bi ( z ) this accuracy can be increased considerably by use of the exponentially-improved forms of expansion supplied in §9.7(v). …
12: 13.7 Asymptotic Expansions for Large Argument
§13.7(iii) Exponentially-Improved Expansion
13: 2.11 Remainder Terms; Stokes Phenomenon
§2.11(iii) Exponentially-Improved Expansions
For this reason the expansion of E p ( z ) in | ph z | π - δ supplied by (2.11.8), (2.11.10), and (2.11.13) is said to be exponentially improved. …
§2.11(v) Exponentially-Improved Expansions (continued)
For another approach see Paris (2001a, b). …
14: 10.17 Asymptotic Expansions for Large Argument
§10.17(v) Exponentially-Improved Expansions
15: 8.22 Mathematical Applications
plays a fundamental role in re-expansions of remainder terms in asymptotic expansions, including exponentially-improved expansions and a smooth interpretation of the Stokes phenomenon. …
16: 5.11 Asymptotic Expansions
§5.11(ii) Error Bounds and Exponential Improvement
For error bounds for (5.11.8) and an exponentially-improved extension, see Nemes (2013b). …
17: 8.12 Uniform Asymptotic Expansions for Large Parameter
c 5 ( 0 ) = - 27 45493 81517 36320 .
The last reference also includes an exponentially-improved version (§2.11(iii)) of the expansions (8.12.4) and (8.12.7) for Q ( a , z ) . …
18: 5.17 Barnes’ G -Function (Double Gamma Function)
For error bounds and an exponentially-improved extension, see Nemes (2014). …
19: 10.40 Asymptotic Expansions for Large Argument
§10.40(iv) Exponentially-Improved Expansions
20: 9.7 Asymptotic Expansions
§9.7(v) Exponentially-Improved Expansions