Polar Representation of Complex Numbers
You would be already aware of the Cartesian or the XY – plane or the Z - plane, that is used to represent any given pair of a point graphically. It has two mutually perpendicular axes namely the x-axis and the y-axis. Hence any ordered pair (x, y) can be located on this XY – plane. This Cartesian plane is used for locating any given pair of the real numbered points.
Argand plane is also a kind of the XY – plane or the Cartesian plane, however, here you consider the x-axis as the real axis and the y-axis as the imaginary axis. And thus the argand plane is used for locating the complex numbers in a graphical manner. In this article, we will learn about the argand plane and the polar representation of complex numbers in detail.
Argand Diagram
Any complex number in the form of z = a + ib can be treated as the ordered pair (a, b) and can be represented accordingly on the argand plane.
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Consider the following example:
Consider z = 2 + 3i
You have Re(z) = 2 and Im(z) = 3
The distance of any given point from the origin is known as its Modulus and is denoted by |z| for any given complex number z.
If the complex number is purely a real number, that is, its imaginary part is zero or (b = 0), then on the argand plane, it is purely located on the real axis either towards the right or the left of the origin depending on the sign of the given number. This means that any given point on the real axis would be in the form of z = a + i0.
While for the purely imaginary number, that is, its real part is zero or (a = 0), on the argand plane it is located on the imaginary axis either toward the upwards or downwards of the origin depending on the sign of the number’s imaginary part. This means that any point on the imaginary axis would be in the form of z = 0 + ib.
The amplitude of any given complex number refers to the angle that is made by the complex number on the argand plane from the plane’s positive real axis.
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Polar Form of Complex Numbers
Let us now learn about the polar form of complex numbers and how to represent a complex number in polar form.
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Consider that A represents the non-zero complex number x + iy. Here, OA is the directed line segment having the length r which makes an angle θ along the positive direction of the x-axis.
The ordered pair (r, θ) is referred to as the polar coordinates of the point A because point A is uniquely determined by (r, θ). The origin is known as the pole and the positive x-axis is referred to as the initial line.
Then you would get,
x = r cosθ
y = r sinθ
You can write this as
z = x + iy as z = r cosθ + ir sinθ = r(cosθ + i sinθ)
This is referred to as the polar form of the given complex number.
Here,
r = |z| = \[\sqrt{(x^{2}+y^{2})}\] is known as the modulus of z and θ is called the argument or the amplitude of z which is denoted as arg z
For any given non-zero complex number z, there is one value of θ in the interval (0, 2π).
In any given other interval having the length 2π, for example, consider the interval -π < θ ≤ π the value of the θ is known as the principal argument of z.
Solved Examples
Let us understand the argand plane and the polar form of complex numbers with some solved examples.
Example 1
Find the modulus and the amplitude for the given complex number z = -1- i.
Solution:
The modulus is given by |z| = \[\sqrt{(x^{2}+y^{2})}\].
For z=a+ib, find the value of the acute angle of which is \[\theta = tan^{-1}|\frac{y}{x}|\].
Then look for the values of (a, b).
If (a, b) lies in the first quadrant of the plane, Argument = θ.
If (a, b) lies in the second quadrant of the plane, Argument = π - θ .
If (a, b) lies in the third quadrant of the plane, Argument = -π + θ.
If (a, b) lies in the fourth quadrant of the plane, Argument = − θ.
Hence, |z| = \[\sqrt{2}\]
The acute angle is given by
\[\theta = tan^{-1}|\frac{y}{x}|\].
Hence, θ = π/4
Hence, arg = -3π/4
Example 2
Represent the equation z = √3 + i in the polar form.
Solution:
√3 = r sin θ
= 1 = r sin θ
r = |z| = \[\sqrt{3+1}\]
= 2
sin θ = \[\frac{1}{2}\] and cos θ =\[\frac{\sqrt{3}}{2}\]
This gives θ = π/6
Hence, the polar form of z is given by
Z = 2 ( cos (π/6) + i sin (π/6) )
FAQs on Argand Plane
1. What exactly is an Argand plane?
An Argand plane, also known as the complex plane, is a two-dimensional coordinate system used to give a geometric representation to complex numbers. Unlike a standard Cartesian plane that plots pairs of real numbers, the Argand plane has a horizontal axis called the real axis and a vertical axis called the imaginary axis. A complex number z = x + iy is plotted as the point (x, y).
2. What is the main difference between a Cartesian plane and an Argand plane?
The primary difference lies in what they represent.
- A Cartesian plane is used to plot ordered pairs of real numbers (x, y), where both axes represent real number lines.
- An Argand plane is specifically designed to plot complex numbers. The horizontal axis represents the real part of the number, and the vertical axis represents the imaginary part.
3. How do you plot a complex number, for example, z = 4 - 3i, on an Argand plane diagram?
To plot the complex number z = 4 - 3i, you first identify its real and imaginary parts. Here, the real part is x = 4 and the imaginary part is y = -3. On the Argand plane, you move 4 units along the positive real (horizontal) axis and 3 units down the negative imaginary (vertical) axis. The point where you land, (4, -3), is the graphical representation of the complex number z = 4 - 3i.
4. Why is the Argand plane an important tool in understanding complex numbers?
The Argand plane is crucial because it transforms abstract algebraic quantities (complex numbers) into concrete geometric forms (points or vectors). This visualisation helps in understanding key concepts more intuitively:
- Modulus: Seen as the distance from the origin.
- Argument: Seen as the angle with the positive real axis.
- Operations: Geometric interpretations for addition (vector addition) and multiplication (rotation and scaling) of complex numbers become clear.
5. How does the Argand plane help in visualising the polar representation of a complex number?
The Argand plane is the foundation for polar representation. When a complex number z = x + iy is plotted as a point P(x, y), the polar form uses two different parameters to locate this point:
- r (Modulus): The distance of the point P from the origin (O).
- θ (Argument): The angle that the line segment OP makes with the positive direction of the real axis.
6. What do the modulus and argument of a complex number represent geometrically on the Argand plane?
Geometrically, the modulus and argument define the location of a complex number in polar terms on the Argand plane.
- The modulus (|z|) represents the straight-line distance of the point representing the complex number from the origin (0,0). It is a measure of the number's magnitude.
- The argument (arg(z)) is the angle formed by the line connecting the origin to the point, measured counter-clockwise from the positive real axis. It defines the direction of the number.
7. Can you plot purely real or purely imaginary numbers on an Argand plane?
Yes. The Argand plane includes the real and imaginary axes to represent these special cases:
- A purely real number (e.g., z = 5 or z = 5 + 0i) has an imaginary part of zero. It is plotted directly on the real axis at the point (5, 0).
- A purely imaginary number (e.g., z = -2i or z = 0 - 2i) has a real part of zero. It is plotted directly on the imaginary axis at the point (0, -2).
