Complex number
A complex number is a number composed of two parts - a real component and an imaginary component, of the form 
, where a and b are real numbers and 
.
Whereas the real numbers can be represented as all the possible points on an infinitely extended number line, to represent all the complex numbers requires the use of a two dimensional coordinate system, usually with the real components on the horizontal axis (the abscissa) and the imaginary components on the vertical axis (the ordinate). This representation is known as the Argand diagram.
The complex numbers form an algebraically closed field but do not permit a non-trivial ordering that is preserved under operations. They are the algebraic closure of the real numbers. One notable consequence, and a very natural way of seeing the necessity of complex numbers is the fact that all matrices of full rank over a vector space over real numbers repesent transformations, which, after a base transformation, are equivalent to a diagonal matrix of the same size with complex entries on the diagonal. Thus, any linear linear equation of motion of arbitrary order and dimension of real numbers can be represented in this way and be decomposed into eigenvectors (or modes). The evolution of the system is fully described by the complex amplitudes.
Many functions used in real analysis can be extended in to complex numbers using Taylor series. This is the subject of complex analysis.
It is a common belief that complex numbers have a weaker connection to physical reality than real numbers. Observables in Physics for example weight, energy, pressure etc. are usually represented as real numbers, and the SI system of units relies on real numbers. However, the transformation between a SI base unit, e.g. an inductance/capacitance/resistance value and a complex impedance is arbritrary and set by convention, and the "natural" representation depends on the measurement method. As a matter of fact, a number of measurement devices (network analysers, lock in amplifiers) directly output real and imaginary component (where the imaginary component is obviously a real voltage/current value).
Polar notation
The complex number can also be written in the form 
, where
-
is the square of the number's magnitude -
,where 
is the phase
If a line is drawn on the complex plane (also known as an 'Argand diagram' or the 'Argand plane') from the origin to a given complex number, the length of that line will be 
and the angle it makes to the real (horizontal) axis will be . This leads to a straight-forward geometric interpretation for multiplication by a complex number: multiplying a complex number by 
is equivalent to an anticlockwise rotation through an angle in the complex plane.
Complex Numbers as Matrices
The field F on complex numbers is isomorphic to the field F' of 2x2 matrices of the form
- [a -b]
- [b a],
with mapping as a function f to the above matrix.
We can see that F and F' are isomorphic because:
The function f is clearly 1-to-1 and onto,
,
and 
.
In popular culture
In Yvgeny Zamyatin's satirical novel We, the narrator's psychological distress at contemplating the concept of complex numbers becomes a metaphor for the limitations of totalitarian systems of thought.
