Integration· [x(tk) - x(tk-1) + i(y(tk) - y(tk-1))]
= if3 [u(x(t), y(t)) dx(t) - v(x(t), y(t)) dy(t)]
- i 1: [v(x(t), y(t)) dx(t) + u(x(t), y( t)) dy(t)]
= j ( u dx -v dy) + i i ( v dx + u d~)
'Y435In the case of a continuously differentiable arc, or of a piecewise con-
tinuously differentiable arc, formulas (7.8-19) and (7.8-20) are applied to
evaluate the corresponding line integrals. Formula (7.8-14) may be used
to evaluate a complex integral in terms of the two components real line
integrals. Also, it may be used to derive a number of properties of the
complex integral.
Example To find J'Y z^2 dz,. where "(: z = t - it^2 , 0 S t S 1. In this case
u = x^2 -y^2 , v = 2xy, x = t, y = -t^2 • Hence·j z^2 dz= j[(x^2 - y^2 ) dx - 2xy dy] +if [(2xy dx + (x^2 - y^2 ) dy]
'Y 'Y 'Y= fo\t2 -5t^4 ) dt + i fo-4t^3 + 2t^5 ) dt
= - ~ (1 + i)
37.9 Cauchy's Fundamental Theorem
The following theorem, due to A. L. Cauchy [7], is of fundamental
importance in the theory of complex integration.
Theorem 7.11 Suppose that f is analytic in a simply or ,multiply con-
nected region R, that f' is continuous in R, and let 0 be a simple closed
contour homotopic to a point in R. Thenj f(z)dz = 0 (7.9-1)
cwhere 0 is described once in either direction (Fig. 7.5).
Remark In view of Theorem 6.37 it is clear that the hypothesis of the
continuity of f' in R is superfluous. The following proof of Cauchy's the-