692 Chapter9More generally, for any integral of the form1
(^00) xmdx
o xn +an
where m and n are positive integers with m :::; n - 2 and a > 0, we may
proceed in a similar manner by using now as a contour c+ the boundary
of a circular sector with the initial ray along the real axis (as in Fig. 9.14)and the terminal side with argument 27r /n. If R > a, this sector contains
only one pole of f(z) = zm /(zn +an), namely, b 0 = aein:/n, and the residueof f at bo is
Res J = ___!!L = .! b:J'-n+l = .!_ am-n+l ei(m-n+l)n:/n
z=bo nb~-l n n
Hence with the same notation as above, we have1
R _xm dx + J zm dz - ei(m+1)2n:/n 1R xm dx
o xn + an zn + an o xn + an
r+
= 27ri am-n+lei(m-n+I)n:/n (9.11-7)
n
Letting R --t oo, the second integral on the left tends to zero (by
Corollary 9.5), and (9.11-7) yields
{oo xm dx
Jo xn +an27ri ei(m+I)n:/ne-in:
= -am-n+l __ ~~-~
n · 1 _ ei(m+l)2n:/n
7r am-n+l
=
;:; sin[(m + l)7r/n](9.11-8)Note The preceding method does not require that the integrand be even.Formula (9.11-8) is due to 0. J. Farrell and B. Ross [4]. For
generalizations of this result, see [17] and [22].
Type II. J!°: f( x) dx, where f ( x) satisfies the same conditions as in
type I, except that [ is not even.
Both integrals f_ 00 f ( x) dx and f 0
00
f ( x) dx exist because of condi-
tions (2) and ( 4). Hence the value of the given integral is the same aslimR-+oo J!:R f( x) dx. Thus we get from (9.11-2),
1
+00 m
-oo f(x)dx=27ri~!l~~f(z)
k=l(9.11-9)As before, this formula applies, in particular, to rational functions f(z) =
P(z)/Q(z) with the degree of Q at least two units greater than that of P.Example To evaluate J~:[(x + 1)/(x^4 + 1)] dx. The poles of the inte-
grand lying on the upper half-plane are bk = ei(n:/4+kn:/Z) (k = 0, 1), and