by |z|=
√x^2 +y^2 which represents the distance of the point zfrom the origin in the
z−plane. (ii) The quantity |z−z 0 |=Rrepresents a circle of radius Rsince
|z−z 0 |=|x+iy −(x 0 +iy 0 )|=|(x−x 0 ) + i(y−y 0 )|=√
(x−x 0 )^2 + (y−y 0 )^2 =Ror (x−x 0 )^2 + (y−y 0 )^2 =R^2
Figure 12-14. The complex z−plane.
In the theory of complex variables there is an important type of series called the
Laurent^8 series which represents a function f(z) in an expansion about a singular
point z 0 having the form of a power series having both positive and negative powers
of (z−z 0 ). The point z 0 is called the center of the Laurent series. The Laurent series
has the form
f(z) =∑∞n=1cn
(z−z 0 )n+∑∞n=0αn(z−z 0 )n (12.192)where the quantities c 1 , c 2 ,... and α 0 , α 1 ,... are constants. In expanded form the
Laurent series (12.192) becomes
f(z) = ··· + c^3
(z−z 0 )^3+ c^2
(z−z 0 )^2+ c^1
(z−z 0 )+α 0 +α 1 (z−z 0 ) + α 2 (z−z 0 )^2 +··· (12.193)The Laurent series converges in some annular region R 2 <|z−z 0 |< R 1. It can be
shown that the series
∑∞n=0αn(z−z 0 )nconverges for zin the circular region |z−z 0 |< R 1
and the series
∑∞n=1cn(z−z 0 )n converges for the circular region |z−z^0 |> R^2 Here R^1 and
(^8) Pierre Alphonse Laurent (1813-1854) A French mathematician who studied complex analysis.