Represent Operations Geometrically on the Complex Plane | Lesson 5 of 9
Addition Is Placing Arrows Tip-to-Tail
Represent Operations Geometrically on the Complex Plane | Lesson 5 of 9
The Parallelogram Rule for Addition
Draw and as arrows from the origin
Complete the parallelogram
Sum is the diagonal
Triangle inequality:
Represent Operations Geometrically on the Complex Plane | Lesson 5 of 9
Subtraction: Reflect w and Add
: reflect through the origin (negate both parts).
: add to →
Represent Operations Geometrically on the Complex Plane | Lesson 5 of 9
Conjugation: Reflection Across the Real Axis
reflects across the real axis (horizontal axis).
→
Same horizontal position, mirrored vertically.
Conjugate pairs are symmetric about the real axis.
Represent Operations Geometrically on the Complex Plane | Lesson 5 of 9
Quick Check: Three Geometric Operations
For and :
Plot using the parallelogram rule. What is ?
Plot by reflecting and adding. What is ?
Plot . Describe its position.
Represent Operations Geometrically on the Complex Plane | Lesson 5 of 9
Powers of i: A Rotation Discovery
Each multiplication by is a 90° counterclockwise rotation.
: four steps, full circle.
Represent Operations Geometrically on the Complex Plane | Lesson 5 of 9
Multiplying by i Rotates 90° Counterclockwise
has modulus and argument .
Multiplying any by : preserves length, adds 90° to direction.
Example: at angle
at angle () ✓
Represent Operations Geometrically on the Complex Plane | Lesson 5 of 9
General Rule: Moduli Multiply, Arguments Add
For and :
Moduli multiply. Arguments add. Not the other way around.
Represent Operations Geometrically on the Complex Plane | Lesson 5 of 9
Multiplication in Polar Form: Example
using polar form:
has ,
Square: ,
Verify algebraically: ✓
Represent Operations Geometrically on the Complex Plane | Lesson 5 of 9
Find the Error in Each Statement
A student writes:
for ,
for computing the argument of a product
What is wrong in each? State the correct rule.
Represent Operations Geometrically on the Complex Plane | Lesson 5 of 9
Quick Check: Rotation and Scaling
For and :
What is the geometric effect of multiplying by ?
Compute in polar form. Verify algebraically.
Hint: has modulus 1 and argument (or ).
Represent Operations Geometrically on the Complex Plane | Lesson 5 of 9
The Hard Way: Expand Algebraically
Step 1:
Step 2:
Eight products, three rounds of like-term collection. Every step is an error opportunity.
Represent Operations Geometrically on the Complex Plane | Lesson 5 of 9
De Moivre's Theorem: Multiply the Argument
Rule: Raise modulus to . Multiply argument by .
Multiply by — do not raise to .
Represent Operations Geometrically on the Complex Plane | Lesson 5 of 9
The Canonical Example:
Step 1:
Step 2: (second quadrant: )
Step 3: Cube: ,
Step 4:
Represent Operations Geometrically on the Complex Plane | Lesson 5 of 9
Second Example:
: ,
Apply De Moivre: ,
Verify algebraically: , ✓
Represent Operations Geometrically on the Complex Plane | Lesson 5 of 9
Three Computations: No Help Provided
Compute and describe the result geometrically.
Compute using polar form. Verify algebraically.
Compute using De Moivre's theorem.
Represent Operations Geometrically on the Complex Plane | Lesson 5 of 9
Watch for These Two Common Errors
— the diagonal is shorter.
— arguments add:
De Moivre: , not .
Represent Operations Geometrically on the Complex Plane | Lesson 5 of 9
What You Now Know: Geometry of Operations
✓ Addition: parallelogram rule;
✓ Subtraction: tip-to-tail with
✓ Conjugation: reflection across the real axis
✓ Multiplication: ,
✓ Powers: De Moivre — and
Represent Operations Geometrically on the Complex Plane | Lesson 5 of 9
Next Lesson: Distance on the Complex Plane
In HSN.CN.B.6, you'll compute the distance between two complex numbers.
The subtraction you learned today gives the distance vector. The modulus gives its length.