Complex numbers in the form $x+i y$ and $r \e^{i\theta}$; complex plane and representation by 2D vectors
Fundamental Theorem of Algebra: polynomial equation of order $n$ as $(z-z_1)(z-z_2)\ldots(z-z_n)=0$
The $n$-th roots of unity: $\e^{i2\pi/m}$ for $ 1 \le m \le n$
Sets of points; interior, boundary and exterior points; open sets; curves and regions of the complex plane.
Spiegel 1.1-1.5, 1.7, 1.8, 1.10-1.14, 1.18
Riley 2; Boas 2; Arfken 6.1
Functions of complex numbers
Real and imaginary parts of functions: $f(z)=u(x,y)+iv(x,y)$
Standard functions - ratios of polynomials, exponential and log, trig and hyperbolic trig functions
Multiple-valued functions; non-integer powers and log; principal values of functions ${\rm Ln}(z)$;
branches and branch cuts
Spiegel 2.1-2.7
Riley 18.1, 18.5; Boas 14.1; Arfken 6.1
Functions as mappings
Mappings of points, curves and regions from the $z$ plane to the plane of $w=f(z)$
Curves which circle $z_0$ in the $z$-plane map to curves which circle the origin in the $w$ plane if
$f(z_0)=0$
The argument theorem: $\Delta\phi=n$
In the diagrams above the blue and red lines are the mappings of the lines $x=$ const and $y=$ const,
and the black dot is the mapping of the point $z=0$.
Spiegel 2.4-2.7
(Riley 14.8); (Boas 14.9); Arfken 6.6
Differentiation and Cauchy-Riemann equations
Definition of derivative: $$\frac{\d f}{\d z}=\lim_{\Delta z\rightarrow 0}\frac{f(z+\Delta z)-f(z)}{\Delta z}$$
Derivative must be finite and independent of direction
