Learn on PengienVision, Mathematics, Grade 8Chapter 6: Congruence and Similarity

Lesson 3: Analyze Rotations

In this Grade 8 lesson from enVision Mathematics Chapter 6, students learn how to perform and describe rotations of two-dimensional figures on a coordinate plane, including applying coordinate rules for 90°, 180°, and 270° counterclockwise rotations about the origin. Students practice identifying the center of rotation, angle of rotation, and the difference between clockwise and counterclockwise directions. The lesson also covers how rotations preserve the size, shape, and properties of the original figure, such as parallel sides and angle measures.

Section 1

Defining a Rotation: Center, Angle, and Direction

Property

A rotation is a rigid transformation that "turns" a figure around a fixed anchor point called the Center of Rotation. Because it is a rigid motion, the figure keeps its exact size and shape. To perfectly describe a rotation, you must have three pieces of information:

The Center: The fixed dot the shape spins around.
The Angle: How far it spins (e.g., $90^\circ$ , $180^\circ$ ).
The Direction: Clockwise (CW, like a clock) or Counterclockwise (CCW, opposite of a clock).

Note: In mathematics, Counterclockwise (CCW) is always the standard, "positive" direction.

Examples

Macro View: Think of a Ferris wheel. The center hub is the "Center of Rotation," and the passenger cars travel in circular paths around it. The cars don't change size as they spin.
Micro Detail (Direction Equivalence): Spinning $90^\circ$ Clockwise lands you in the exact same spot as spinning $270^\circ$ Counterclockwise ( $360^\circ - 90^\circ = 270^\circ$ ).
Micro Detail (Distance): If point $A$ is 5 inches away from the center of rotation, its image $A'$ will also be exactly 5 inches away from the center.

Explanation

A common mistake is thinking the shape just rotates in place. Unless the center of rotation is inside the shape, the entire shape travels along an invisible circular track to a new location on the graph. The center point is the only thing in the entire universe that does not move during a rotation!

Section 2

Coordinate Rules for Rotations (About the Origin)

Property

When the center of rotation is the origin $(0,0)$ , we use algebraic rules to find the new coordinates. Assume all angles are Counterclockwise (CCW) unless stated otherwise.

$90^\circ$ CCW: $(x, y) \rightarrow (-y, x)$ [Swap the numbers, change the sign of the NEW first number]
$180^\circ$ : $(x, y) \rightarrow (-x, -y)$ [Do NOT swap numbers, just change BOTH signs]
$270^\circ$ CCW (or $90^\circ$ CW): $(x, y) \rightarrow (y, -x)$ [Swap the numbers, change the sign of the NEW second number]

Examples

$90^\circ$ CCW Rotation: Rotate $A(4, 5)$ .
- Step 1 (Swap): $(5, 4)$
- Step 2 (Change first sign): $(-5, 4)$ . So, $A'(-5, 4)$ .
$180^\circ$ Rotation: Rotate $B(-2, 7)$ .
- Keep the order, flip both signs: $(+2, -7)$ . So, $B'(2, -7)$ .
$90^\circ$ CW (which is $270^\circ$ CCW): Rotate $C(-3, -6)$ .
- Step 1 (Swap): $(-6, -3)$
- Step 2 (Change second sign): $(-6, +3)$ . So, $C'(-6, 3)$ .

Explanation

This is where the most errors happen! Students often try to swap the numbers and change the signs at the exact same time in their heads, which leads to messy mistakes with negatives. Always do it in two micro-steps: Write down the swapped numbers first, then apply the negative sign to the correct position. Also, remember that a $180^\circ$ rotation rule $(-x, -y)$ looks exactly like reflecting across both the x and y axes!

Lesson overview

Expand to review the lesson summary and core properties.

Expand

Section 1

Defining a Rotation: Center, Angle, and Direction

Property

The Center: The fixed dot the shape spins around.
The Angle: How far it spins (e.g., $90^\circ$ , $180^\circ$ ).
The Direction: Clockwise (CW, like a clock) or Counterclockwise (CCW, opposite of a clock).

Note: In mathematics, Counterclockwise (CCW) is always the standard, "positive" direction.

Examples

Macro View: Think of a Ferris wheel. The center hub is the "Center of Rotation," and the passenger cars travel in circular paths around it. The cars don't change size as they spin.
Micro Detail (Direction Equivalence): Spinning $90^\circ$ Clockwise lands you in the exact same spot as spinning $270^\circ$ Counterclockwise ( $360^\circ - 90^\circ = 270^\circ$ ).
Micro Detail (Distance): If point $A$ is 5 inches away from the center of rotation, its image $A'$ will also be exactly 5 inches away from the center.

Explanation

Section 2

Coordinate Rules for Rotations (About the Origin)

Property

When the center of rotation is the origin $(0,0)$ , we use algebraic rules to find the new coordinates. Assume all angles are Counterclockwise (CCW) unless stated otherwise.

$90^\circ$ CCW: $(x, y) \rightarrow (-y, x)$ [Swap the numbers, change the sign of the NEW first number]
$180^\circ$ : $(x, y) \rightarrow (-x, -y)$ [Do NOT swap numbers, just change BOTH signs]
$270^\circ$ CCW (or $90^\circ$ CW): $(x, y) \rightarrow (y, -x)$ [Swap the numbers, change the sign of the NEW second number]

Examples

$90^\circ$ CCW Rotation: Rotate $A(4, 5)$ .
- Step 1 (Swap): $(5, 4)$
- Step 2 (Change first sign): $(-5, 4)$ . So, $A'(-5, 4)$ .
$180^\circ$ Rotation: Rotate $B(-2, 7)$ .
- Keep the order, flip both signs: $(+2, -7)$ . So, $B'(2, -7)$ .
$90^\circ$ CW (which is $270^\circ$ CCW): Rotate $C(-3, -6)$ .
- Step 1 (Swap): $(-6, -3)$
- Step 2 (Change second sign): $(-6, +3)$ . So, $C'(-6, 3)$ .

Explanation

Overview

Lesson overview

Review the lesson summary and core properties without leaving the current page.

Overview

Section 1

Defining a Rotation: Center, Angle, and Direction

Property

The Center: The fixed dot the shape spins around.
The Angle: How far it spins (e.g., $90^\circ$ , $180^\circ$ ).
The Direction: Clockwise (CW, like a clock) or Counterclockwise (CCW, opposite of a clock).

Note: In mathematics, Counterclockwise (CCW) is always the standard, "positive" direction.

Examples

Macro View: Think of a Ferris wheel. The center hub is the "Center of Rotation," and the passenger cars travel in circular paths around it. The cars don't change size as they spin.
Micro Detail (Direction Equivalence): Spinning $90^\circ$ Clockwise lands you in the exact same spot as spinning $270^\circ$ Counterclockwise ( $360^\circ - 90^\circ = 270^\circ$ ).
Micro Detail (Distance): If point $A$ is 5 inches away from the center of rotation, its image $A'$ will also be exactly 5 inches away from the center.

Explanation

Section 2

Coordinate Rules for Rotations (About the Origin)

Property

When the center of rotation is the origin $(0,0)$ , we use algebraic rules to find the new coordinates. Assume all angles are Counterclockwise (CCW) unless stated otherwise.

$90^\circ$ CCW: $(x, y) \rightarrow (-y, x)$ [Swap the numbers, change the sign of the NEW first number]
$180^\circ$ : $(x, y) \rightarrow (-x, -y)$ [Do NOT swap numbers, just change BOTH signs]
$270^\circ$ CCW (or $90^\circ$ CW): $(x, y) \rightarrow (y, -x)$ [Swap the numbers, change the sign of the NEW second number]

Examples

$90^\circ$ CCW Rotation: Rotate $A(4, 5)$ .
- Step 1 (Swap): $(5, 4)$
- Step 2 (Change first sign): $(-5, 4)$ . So, $A'(-5, 4)$ .
$180^\circ$ Rotation: Rotate $B(-2, 7)$ .
- Keep the order, flip both signs: $(+2, -7)$ . So, $B'(2, -7)$ .
$90^\circ$ CW (which is $270^\circ$ CCW): Rotate $C(-3, -6)$ .
- Step 1 (Swap): $(-6, -3)$
- Step 2 (Change second sign): $(-6, +3)$ . So, $C'(-6, 3)$ .