690 Chapter^9
_L 1_b4~-·b_3-=-t-·~·b_2~~--,:-~ •b1
-R 0Fig. 9.la
Since f(z) is even, we have J~n J(x) dx = f 0 R f(x) dx and (9.11-2) becomes
R m
2 f f(x)dx+ f J(z)dz=21f"iLResf(z)lo lr+ k=l z=bk
In view of (9.11-1) and Lemma 9.3, we haveR->oo lim jJ(z)dz =^0
r+
Hence if we take limits in (9.11-3) as R --+ oo we getafter dropping the factor 2.(9.11-3)(9.11-4)Formula (9.11-4) applies, in particular, to rational functions of the form
J(x) = P(x)/Q(x), where P and Q are polynomials prime to each other
and such that the degree of Q is at least two units greater than the degreeof P, provided f is even and there are no poles of f lying on the real axis.
Clearly, if the degrees of P and Q satisfy the condition stipulated above,
we have f(z) = 0(1/zOI) with a ~ 2.Example To evaluate J 0
00
x^4 dx/(x^6 + 1). The integrand admits the ex-
tension J(z) = z^4 /(z^6 +1) into the complex domain and f(z) satisfies the
conditions required for the application of (9.11-4), so that all we need is to
evaluate the right-hand side of that formula. The poles off lying in the
upper half-plane are bk = ei(rr/^6 +krr/^3 ) (k = 0, 1, 2, ), and by (9.8-2),Res~= bts = ~b"kl
z=bk z^6 + 1 6bk 6