Complex Numbers 29correspondence between the complex numbers and the vectors with the
origin 0, provided that we associate the zero complex number (0, 0) to thezero of null vector 00. This representation of complex numbers by vectors
of origin 0 will be widely used in what follows.
We note that the projections OP' and OP" of the vector OP upon
the axes OX and OY, respectively, have signed measures equal to a and
b, respectively. Denoting the signed measures of OP' and OP", by OP
1
-II
and OP , we haveand op" =b
On the other hand, the length r of the vector OP is given byr = y' a2 + b2 = lzl (1.7-1)
The measure B in radians of the oriented angle from the positive real axis
to the vector OP is called the argument or the amplitude of the vector
OP, as well as of the corresponding number z -:/-O, and we writeB = argz (1.7-2)This number B is determined only up to multiples of 27r. Sometimes the
angle itself, also denoted B, is called the argument (or the amplitude) of
OP, or of the number z, but this seldom causes any confusion.
In most cases it is convenient to choose a principal value, or determina-
tion, or branch of the argument. Usually we shall select, as the principalvalue of the argument, the value Bo satisfying the inequality -7!" < Bo ::=; 7r,
and writeBo= Argz ,(1.7-3)to denote this value. Hencearg z = Arg z + 2k7r (1.7-4)
where k is an arbitrary integer. However, in some situations it is moreconvenient to select the value B 1 satisfying the inequality 0 ::=; Bl < 27r as
the principal value of the argument. In either case the principal value of
the argument of z results in a discontinuous function of z. This is discussed
in more detail in Section 3.12. For the complex number z = 0 the argument
is not defined, so that arg z is not continuous in the whole plane either.
From trigonometry we have, for z -:/-0,
a Rez
cosB = -
; - Tzl'sinB = ~ =
rImz
Tzf(1.7-5)