340 Chapter^6and the directional derivative of the given function at z 0 E 'Y* (in the
direction of 'Y) is given byf' 'Y (z 0 ) = 2to(l 1 + + 2ito 2t~) = zo + zoe-2i8o
where ei^80 = (1 + 2it 0 )/(1 + 4tn^112 •
The existence of the directional derivative off at a point zo of a regulararc 'Y implies the continuity of f at z 0 along the arc, as shown in the
following theorem.Theorem 6.11 Let f be defined along a regular arc 'Y· If f has a di-
rectional derivative at zo E 'Y*, then f is continuous at zo along the arc.
However, a continuous function at z 0 E 'Y* (along 'Y) may fail to have a
directional derivative at z 0 •Proof We havef(z) = f(zo) + f(z)-f(zo) (z - z 0 )
Z-Zofor z E -y*. If z = z(t), a :::; t:::; /3, defines the arc"'(, and if z(to) = z 0 ,
letting t --+ t 0 we have z(t) --+ z(t 0 ) = z 0 • Then it follows that
)i..IIJ 0 f(z) = f(zo) + f~(zo) · 0 = f(zo)
ZE'"'f*which shows that f is continuous at zo along 'Y·
To see that the converse does not hold, consider the followingExample Let f(z) = zsin(l/Rez) for z-=/= 0 and f(O) = 0. This function
is continuous along the line segment z = t +it (0:::; t:::; 1). Yet it does not
have a directional derivative along the segment at z = O, since
f(z) - f(O)
z-0. 1
= Sln -
t
which has no limit as t --t o+.Remark It is clear that one-sided derivatives of real functions may be
considered as directional derivatives of such functions at z = x in thedirection of the real line segment z = t (a:::; t:::; b), or else, z = a+ b - t
(a :::; t :::; b ).