Integration 413we haveg(t) = lt u(r)dr, h(t) = lt v(r)dr
so thatg'(t) = u(t), h'(t) = v(t)
andG'(t) = g'(t) + ih'(t) = u(t) + iv(t) = f(t)
To prove property 11, let f(t,s) = u(t,s) + iv(t,s) and F(s) = U(s) +
iV(s). ThenU(s) =lb u(t, s) dt, V(s) =lb v(t, s) dt
Since fs(t, s) is supposed to exist and be continuous on R, the partial
derivatives Us(t, s) and v 8 (t, s) also exist and are continuous on R. Hence,
by a known property of real integrals ([2], p. 219), we haveU'(s) =lb u 8 (t,s)dt, V'(s) =lb v 8 (t,s)dt
for s E (c, d]. Hence it follows that
F'(s) = U'(s) + iV'(s) =lb fs(t, s) dt
7 .3 INTEGRAL OF A COMPLEX FUNCTION OF A
COMPLEX VARIABLE ALONG A CONTINUOUSLY
DIFFERENTIABLE ARCDefinition 7 .3 The definite integral of a continuous complex function
f(z) along (or over) a continuously differentiable arc 1: z = z( t), a :St :S (3,
is defined by the formula
J f(z) dz= L{j J(z(t))z'(t) dt (7.3-1)
'Y
We note that the composite function f(z(t)), as well as z'(t), are con-
tinuous functions of the real variable t on the interval [a, (3]. Hence the
right-hand side of (7.3-1) is an integral of the type considered in Section
7 .2. Thus our definition reduces the integral of a continuous complex func-
tion along a continuously differentiable arc to the integral of a continuous