FAC1004 L01 — Complex Numbers
Introduction to complex numbers: definition, arithmetic operations, polar form, and basic properties.
Key Concepts
- Complex Numbers — definition of $i = \sqrt{-1}$, standard form $z = a + bi$
- Imaginary Unit — powers of $i$ cycle every 4: $i^0 = 1$, $i^1 = i$, $i^2 = -1$, $i^3 = -i$, $i^4 = 1$
- Arithmetic Operations — addition, subtraction, multiplication, division of complex numbers
- Complex Conjugate — $\overline{z} = a - bi$ and its reflection on the Argand Diagram
- Modulus — $|z| = \sqrt{a^2 + b^2}$
- Roots of Complex Numbers — finding square roots of complex numbers by equating real and imaginary parts
- Polar Form — $z = r[\cos\theta + i\sin\theta]$ where $r = |z|$ and $\theta = \arg(z)$
- Principal Argument — $-\pi < \theta \leq \pi$
- Polar Multiplication & Division — $z_1 z_2 = r_1 r_2[\cos(\theta_1 + \theta_2) + i\sin(\theta_1 + \theta_2)]$ and $\frac{z_1}{z_2} = \frac{r_1}{r_2}[\cos(\theta_1 - \theta_2) + i\sin(\theta_1 - \theta_2)]$
Introduction: Solving Quadratic Equations with Negative Discriminant
The lecture begins by motivating complex numbers through quadratic equations that have no real solutions.
- $x^2 = -16$ has no real solution; introducing $i$ gives $x = \pm 4i$
- Example: Find the discriminant for $x^2 - 2x + 17 = 0$
- Using $x = \frac{-b \pm \sqrt{b^2 - 4ac}}{2a}$
- Discriminant $b^2 - 4ac = 4 - 68 = -64 < 0$, so complex roots exist
Definition of Complex Numbers
A complex number is defined as $z = a + ib$ where:
- $a$ is the real part: $\text{Re}(z) = a$
- $b$ is the imaginary part: $\text{Im}(z) = b$
- $i$ is the imaginary unit with $i^2 = -1$
Number System Hierarchy (Lecture Venn Diagram)
$$\mathbb{N} \subset \mathbb{Z} \subset \mathbb{Q} \subset \mathbb{R} \subset \mathbb{C}$$
| $z = a + ib$ | $2 + 3i$ | $-1 - i\pi$ | $10i$ | $3$ | $0$ |
|---|---|---|---|---|---|
| $\text{Re}(z)$ | $2$ | $-1$ | $0$ | $3$ | $0$ |
| $\text{Im}(z)$ | $3$ | $-\pi$ | $10$ | $0$ | $0$ |
Example
For $z = 6 - 3i$:
- $\text{Re}(z) = 6$
- $\text{Im}(z) = -3$
Argand Diagram
The lecture presents the Argand diagram (complex plane):
- Horizontal axis: Real axis
- Vertical axis: Imaginary axis
- A complex number $z = a + ib$ is plotted at point $(a, b)$
- The complex conjugate $\overline{z} = a - ib$ is the reflection of $z$ across the real axis
- The angle $\theta$ from the positive real axis to the line joining the origin to $z$ is the argument
Arithmetic of Imaginary Numbers
Powers of $i$
| $i^0$ | $i^1$ | $i^2$ | $i^3$ |
|---|---|---|---|
| $1$ | $i$ | $-1$ | $-i$ |
| $i^4$ | $i^5$ | $i^6$ | $i^7$ |
|---|---|---|---|
| $1$ | $i$ | $-1$ | $-i$ |
The cycle repeats every 4 powers.
Examples: Express in the form $a + ib$
i) $2i^3 - 3i^2 + 5i$
ii) $3i^5 - i^4 + 7i^3$
iii) $\frac{5}{i} + \frac{2}{i^3} - \frac{20}{i^{18}}$
(Student Version — worked solutions to be completed in class)
Algebraic Operations of Complex Numbers
Given $z_1 = 2 + 4i$ and $z_2 = 1 - 3i$:
i) Subtraction: $$z_1 - z_2 = (2 + 4i) - (1 - 3i)$$
ii) Multiplication: $$z_1 z_2 = (2 + 4i)(1 - 3i)$$
iii) Division: $$\frac{z_1}{z_2} = \frac{2 + 4i}{1 - 3i}$$
(Student Version — worked solutions to be completed in class)
General Formulas
- Addition/Subtraction: $(a + bi) \pm (c + di) = (a \pm c) + (b \pm d)i$
- Multiplication: $(a + bi)(c + di) = (ac - bd) + (ad + bc)i$
- Division: Multiply numerator and denominator by the conjugate of the denominator
Roots of Complex Numbers
Example: Find the square root of $z = 5 + 12i$
Let $z_1 = a + bi$ such that $(z_1)^2 = 5 + 12i$.
Equate real and imaginary parts to solve for $a$ and $b$.
(Student Version — worked solution to be completed in class)
Polar Form
The polar form of a complex number is: $$z = r[\cos\theta + i\sin\theta]$$
Conversion Procedure (4 Steps)
graph LR
START["z = a + bi"] --> S1["Step 1: Identify a and b"]
S1 --> S2["Step 2: Find radius<br/>r = sqrt(a^2 + b^2)"]
S2 --> S3["Step 3: Find angle<br/>theta = arctan(b/a)<br/>adjust quadrant"]
S3 --> S4["Step 4: Write<br/>z = r[cos theta + i sin theta]"]
style START fill:#e7f5ff,stroke:#1971c2
style S1 fill:#ffe8cc,stroke:#d9480f
style S2 fill:#ffe8cc,stroke:#d9480f
style S3 fill:#ffe8cc,stroke:#d9480f
style S4 fill:#d3f9d8,stroke:#2f9e44
Given $z = a + bi$:
- Identify $a$ and $b$
- Find the radius: $r = \sqrt{a^2 + b^2}$
- Find the angle: $\theta = \tan^{-1}\left(\frac{b}{a}\right)$
- Note: $-\pi < \theta \leq \pi$ (Principal Argument)
- Write: $z = r[\cos\theta + i\sin\theta]$
Examples
- Write $z = -4 + 4i$ in polar form
- Write $z = \sqrt{3} - i$ in polar form
(Student Version — worked solutions to be completed in class)
Multiplication and Division in Polar Form
For $z_1 = r_1[\cos\theta_1 + i\sin\theta_1]$ and $z_2 = r_2[\cos\theta_2 + i\sin\theta_2]$:
Multiplication Rule
$$z_1 z_2 = r_1 r_2[\cos(\theta_1 + \theta_2) + i\sin(\theta_1 + \theta_2)]$$
Derivation shown in lecture via expansion and application of cosine/sine addition formulas.
Division Rule
$$\frac{z_1}{z_2} = \frac{r_1}{r_2}[\cos(\theta_1 - \theta_2) + i\sin(\theta_1 - \theta_2)]$$
Example
Find the product and division for:
- $z_1 = -1 + i$
- $z_2 = \sqrt{3} + i$
(Student Version — worked solutions to be completed in class)
mindmap
root((Complex Numbers))
Standard Form z = a + bi
Real part Re(z) = a
Imaginary part Im(z) = b
Argand Diagram
Real axis horizontal
Imaginary axis vertical
Modulus |z| = sqrt(a^2 + b^2)
Argument theta
Operations
Addition/Subtraction
Multiplication
Division via conjugate
Polar Form
z = r[cos theta + i sin theta]
Conversion 4 steps
Multiplication: multiply r add theta
Division: divide r subtract theta
Powers of i
Cycle every 4
i^2 = -1
Summary
This lecture introduces the fundamental concept of complex numbers as an extension of real numbers. Students learn to:
- Identify real and imaginary parts of complex numbers
- Simplify powers of $i$ and express imaginary expressions in $a + bi$ form
- Perform basic arithmetic operations on complex numbers
- Find complex roots by equating real and imaginary parts
- Convert between Cartesian and polar representations
- Multiply and divide complex numbers in polar form
Related
- FAC1004 - Advanced Mathematics II (Computing) — main course page
- Complex Numbers — concept page
- FAC1004 L02 — Euler's Formula — next lecture
- FAC1004 L5-L6 — Functions of Complex Numbers (n-th Roots) — advanced complex functions
Source File
LECTURE_NOTES_2526/L01 - Complex Number Student Version.pdf