APPLICATIONS OF COMPLEX VARIABLES
Then, by the principle of the argument, the number of zeros insideCis given by
the integer (2π)−^1 ∆C[argf(z)].
It can be shown that the zeros ofz^4 +z+ 1 lie one in each quadrant. Use the
above method to show that the zeros in the second and third quadrants have
|z|<1.
25.9 Prove that
∑∞
−∞1
n^2 +^34 n+^18=4π.Carry out the summation numerically, say between−4 and 4, and note how
much of the sum comes from values near the poles of the contour integration.
25.10 This exercise illustrates a method of summing some infinite series.
(a) Determine the residues at all the poles of the functionf(z)=πcotπz
a^2 +z^2,
whereais a positive real constant.
(b) By evaluating, in two different ways, the integralIoff(z) along the straight
line joining−∞−ia/2and+∞−ia/2, show that
∑∞n=11
a^2 +n^2=
πcothπa
2 a−
1
2 a^2.
(c) Deduce the value of∑∞
1 n− (^2).
25.11 By considering the integral of
(
sinαz
αz
) 2
π
sinπz,α<π
2,
around a circle of large radius, prove that
∑∞m=1(−1)m−^1sin^2 mα
(mα)^2=
1
2
.
25.12 Use the Bromwich inversion, and contours similar to that shown in figure 25.7(a),
to find the functions of which the following are the Laplace transforms:
(a) s(s^2 +b^2 )−^1 ;
(b)n!(s−a)−(n+1),withna positive integer ands>a;
(c) a(s^2 −a^2 )−^1 ,withs>|a|.
Compare your answers with those given in a table of standard Laplace transforms.
25.13 Find the functionf(t) whose Laplace transform is
f ̄(s)=e−s−1+s
s^2.
25.14 A functionf(t) has the Laplace transform
F(s)=1
2 iln(
s+i
s−i)
,
the complex logarithm being defined by a finite branch cut running along the
imaginary axis from−itoi.
(a) Convince yourself that, fort>0,f(t) can be expressed as a closed contour
integral that encloses only the branch cut.