25.6 STOKES’ EQUATION AND AIRY INTEGRALS
the integrand. Consider the contour integral
y(z)=∫baf(t) exp(zt)dt, (25.33)in whicha,bandf(t) are all yet to be chosen. Note that the contour is in the
complext-plane and that the path fromatobcan be distorted as required so
long as no poles of the integrand are trapped between an original path and its
distortion.
Substitution of (25.33) into (25.32) yields
∫bat^2 f(t) exp(zt)dt=∫bazf(t) exp(zt)dt=[f(t) exp(zt)]ba−∫badf(t)
dtexp(zt)dt.If we could choose the limitsaandbso that the end-point contributions vanish
then Stokes’ equation would be satisfied by (25.33), providedf(t) satisfies
df(t)
dt+t^2 f(t)=0 ⇒ f(t)=Aexp(−^13 t^3 ), (25.34)whereAis any constant.
To make the end-point contributions vanish we must chooseaandbsuch thatexp(−^13 t^3 +zt) = 0 for both values oft. This can only happen if|a|→∞and
|b|→∞and, even then, only if Re (t^3 ) is positive. This condition is satisfied if
2 nπ−^12 π<3arg(t)< 2 nπ+^12 πfor some integern.Thusaandbmust each be at infinity in one of the three shaded areas shown in
figure 25.10, but clearly not in the same area as this would lead to a zero value
for the contour integral. This leaves three contours (markedC 1 ,C 2 andC 3 in the
figure) that start and end in different sectors. However, only two of them give rise
to independent integrals since the pathC 2 +C 3 is equivalent to (can be distorted
into) the pathC 1.
The two integral functions given particular names areAi(z)=1
2 πi∫C 1exp(−^13 t^3 +zt)dt (25.35)and
Bi(z)=1
2 π∫C 2exp(−^13 t^3 +zt)dt−1
2 π∫C 3exp(−^13 t^3 +zt)dt.
(25.36)Stokes’ equation is unchanged if the independent variable is changed fromz
toζ,whereζ=exp(2πi/3)z≡Ωz. This is also true for the repeated change
z→Ωζ=Ω^2 z. The same changes of variable, rotations of the complex plane
through 2π/3or4π/3, carry the three contoursC 1 ,C 2 andC 3 into each other,