326 CHAPTER 8 • REsIDUE THEORY
Keeping in mind the branch of logarithm that we're using, we then have
fct(z)dz= 1: f(x)dx+ 1-c. f(z)dz+ 1R f(x)dx+ lR f(z)dz
= 1 -rlnl:l +!n dx+j f(z)dz
- R X +a -C.
+1R ;nx 2 dx+ { f(z)dz
r X + a lei<
nlna .71"^2
= --+i -.
a 2aIf R^2 > a^2 , then by the ML inequality (Theorem 6.3)
I
r I (z)dzl = l {" lnR+iO iRei9d8 1
JcR Jo R2e•29 + a2
< R(lnR+n)7r- R2 - a2 '
(8- 33 )and L'Hopital's rule yields lim f.c f (z) dz= O. A similar computation shows
R-oo R
that lim J. f (z) dz = O. We use these results when we take corresponding
r-o+ c,,.
limits in Equations (8-33) to get
P.V. (Jo lnlxl+in dx+ [
00lnx dx) = nlna +i7r
2
- ~+~ k ~+~ a ~
Equating the real parts in this equation gives
l
oo lnx nlna
P.V. 2 2 dx = --.
0 x +a 2a
Remark 8.3 The theory of this section is not purely esoteric. Many applica-
tions of contour integrals surface in government and industry worldwide. Many
years ago, for example, a briefing was given at the Korean Institute for Defense
Analysis (KIDA) in which a sophisticated problem was analY2ed by means of a
contour integral whose path of integration was virtually identical to that given
in Figure 8.8. •
-------... EXERCISES FOR SECTION 8.6
Use residues to computeroo dx- P.V. Jo!.
x (1 + x)
roo dx- P.V. Jo ~.
x (1 + x)