AQA GEOMETRY AND MEASURE
A location in any space is represented by a dot
It does not have any length, height, shape, or size.
Usually labeled with capital letters.
A series of points connected by a straight path.
A line is usually defined by two points and can be marked with a single lowercase letter or two capital letters.
A line has no thickness, and its length is undefined, meaning it can have an infinite number of points.
Types of Points and Lines
There are different types of points in geometry.
Collinear Points
Three or more points that lie on a single straight line
Non-Collinear Points
A group of points that do not lie on the same line
Coplanar Points
A group of points that lie on the same plane
Non-Coplanar Points
A group of points that do not lie on the same plane are non-coplanar points.
There are different types of lines that can be distinguished easily based on their unique properties.
A horizontal line is a line that is mapped from left to right or right to left and parallel to the x-axis in a plane.
A line that is mapped from up to down or down to up and is parallel to the y-axis in a plane is called a vertical line.
When two lines cross each other and meet at a point, they are known as intersecting lines. The point at which they meet is known as the point of intersection.
When two lines intersect exactly at 90°, they are known as perpendicular lines.
Two lines are said to be parallel if they do not intersect at any point and are equidistant.
A polygon is a 2D shape with straight sides. Some polygons have special names, for example, triangles and quadrilaterals.
Polygons can be regular or irregular.
Regular polygon = equal angles and sides
Irregular polygon ≠ equal angles and sides
Triangle: 3 sides
Quadrilateral: 4 sides (includes squares, rectangles, trapezoids, and parallelograms)
Pentagon: 5 sides
Hexagon: 6 sides
Heptagon: 7 sides
Octagon: 8 sides
Polygons can have both interior angles and exterior angles.
An interior angle is the angle formed between two adjacent sides of a polygon on the inside of the shape. Each vertex (corner) of a polygon has an interior angle.
To find the sum of interior angles in a polygon, divide the polygon into triangles. The sum of interior angles in a triangle is 180°.
To find the sum of the interior angles of a polygon, multiply the number of triangles in the polygon by 180°.
Example
Calculate the sum of interior angles in a pentagon.
A pentagon has 5 sides, so it contains 3 triangles.
The sum of the interior angles is: 180º × 3 = 540∘
The formula for calculating the sum of interior angles is:
(𝑛 − 2) × 180º (where 𝑛 is the number of sides)
If the side of a polygon is extended, the angle formed outside the polygon is the exterior angle. The sum of the exterior angles of a polygon is 360°.
The formula for calculating the size of an exterior angle is 360 divided by the number of sides
Example
This pentagon has 5 sides. To calculate the exterior angles, divide 360º by the number of sides
360º / 5 = 72º
Triangles are 2D shapes with three sides. There are four different triangles with different properties.
3 sides of different lengths
3 unequal angles.
2 sides of equal length
The dashes on the lines show they are equal in length
The angles at the base of the equal sides are equal.
3 sides of equal length.
The dashes on the lines show they are equal in length
All of the angles are equal.
A triangle that has a right angle
Letters can be used to label angles.
AB and AC are line segments, and they meet at point A.
Line segment: a line with 2 endpoints
AB joins the points A and B.
The angle between AB and AC is labelled BAC.
The angle can written as BAC or BÂC or ∠BAC.
The angles inside a shape are called interior angles.
If the side of a triangle is extended, the angle formed outside the triangle is the exterior angle.
g = interior angle
h = exterior angle
g + h = 180º
The interior angle and its corresponding exterior angle always add up to 180°.
The sum of interior angles in a triangle is 180°.
To prove 𝑎 + 𝑏 + 𝑐 = 180º, draw a line parallel to one side of the triangle.
𝑑 = 𝑏 (alternate angles are equal)
𝑒 = 𝑐 (alternate angles are equal)
𝑎 + 𝑑 + 𝑒 = 180º (angles on a straight line add up to 180°)
So 𝑎 + 𝑏 + 𝑐 = 180º
These facts can be used to calculate angles.
Triangles are congruent if they are identical in size and shape. This means all corresponding sides and angles are equal.
RHS: RIGHT ANGLE, HYPOTENUSE, SIDE
Both have right angles
Both have the same hypotenuse length
Both have one other pair of sides which are equal
ASA: ANGLE, SIDE, ANGLE
2 pairs of angles are equal
The side between the angles are the same
SAS: SIDE, ANGLE, SIDE
2 pairs of sides are equal
The angle between the pair of equal sides is the same
SSS: SIDE, SIDE, SIDE
All three pairs of sides are equal
Applies to right-angled triangles
States that the square of the length of the hypotenuse (c) is equal to the sum of the squares of the lengths of the other two sides (a and b).
a, b, and c are the lengths of the three sides
a2 + b2 = c2
Given: A right-angled triangle with legs a = 3 cm and b = 4 cm.
Find: The hypotenuse c
c2 = a2 + b2
= 32 + 42
= 9 + 16 = 25
c2 = 25 cm
Square root both sides = 25 → 5 cm
Circle theorems are properties that show relationships between angles within the geometry of a circle.
The angle that lies between a tangent and a chord is equal to the angle subtended by the same chord in the alternate segment.
How to use it:
Locate the key parts of the circle for the theorem
Use other angle facts to determine one of the two angles
Use the alternate segment theorem to state the other missing angle
The angle at the centre is twice the angle at the circumference.
How to use the fact that the angle at the centre is twice the angle at the circumference:
Locate the key parents of the circle for the theorem
Determine the angle at the centre or the angle at the circumference
Use the angle at the centre to state the other missing angle
Angles in the same segment are equal.
How to use the fact that angles in the same segment are equal
Locate the key parts of the circle for the theorem.
Use other angle facts to determine an angle at the circumference in the same segment.
Use the angle in the same segment theorem to state the other missing angle.
The angle in a semicircle is 90 degrees
How to use the fact that angles in a semicircle equal 90º
Locate the key parts of the circle for the theorem.
Use other angle facts to determine angles within the triangle.
Use the angles in a semicircle theorem to state the other missing angle.
The perpendicular from the centre of a circle to a chord bisects the chord (splits the chord into two equal parts).
How to find missing lengths using chords
Locate the key parts of the circle for an appropriate circle theorem.
Use other angle facts to determine any missing angles.
Use Pythagoras’ theorem or trigonometry to find the missing length.
The angle between a tangent and radius is 90 degrees. Tangents which meet at the same point are equal in length.
How to use the tangent of a circle theorems:
Locate the key parts of the circle for the theorem.
Use other angle facts to determine the remaining angle(s) made with the tangent.
Use the tangent theorem to state the other missing angle.
The opposite angles in a cyclic quadrilateral total 180º
How to use the cyclic quadrilateral theorem
Locate the key parts of the circle for the theorem.
Use other angle facts to determine one of the two opposing angles in the quadrilateral.
Use the cyclic quadrilateral theorem to state the other missing angle.
A location in any space is represented by a dot
It does not have any length, height, shape, or size.
Usually labeled with capital letters.
A series of points connected by a straight path.
A line is usually defined by two points and can be marked with a single lowercase letter or two capital letters.
A line has no thickness, and its length is undefined, meaning it can have an infinite number of points.
Types of Points and Lines
There are different types of points in geometry.
Collinear Points
Three or more points that lie on a single straight line
Non-Collinear Points
A group of points that do not lie on the same line
Coplanar Points
A group of points that lie on the same plane
Non-Coplanar Points
A group of points that do not lie on the same plane are non-coplanar points.
There are different types of lines that can be distinguished easily based on their unique properties.
A horizontal line is a line that is mapped from left to right or right to left and parallel to the x-axis in a plane.
A line that is mapped from up to down or down to up and is parallel to the y-axis in a plane is called a vertical line.
When two lines cross each other and meet at a point, they are known as intersecting lines. The point at which they meet is known as the point of intersection.
When two lines intersect exactly at 90°, they are known as perpendicular lines.
Two lines are said to be parallel if they do not intersect at any point and are equidistant.
A polygon is a 2D shape with straight sides. Some polygons have special names, for example, triangles and quadrilaterals.
Polygons can be regular or irregular.
Regular polygon = equal angles and sides
Irregular polygon ≠ equal angles and sides
Triangle: 3 sides
Quadrilateral: 4 sides (includes squares, rectangles, trapezoids, and parallelograms)
Pentagon: 5 sides
Hexagon: 6 sides
Heptagon: 7 sides
Octagon: 8 sides
Polygons can have both interior angles and exterior angles.
An interior angle is the angle formed between two adjacent sides of a polygon on the inside of the shape. Each vertex (corner) of a polygon has an interior angle.
To find the sum of interior angles in a polygon, divide the polygon into triangles. The sum of interior angles in a triangle is 180°.
To find the sum of the interior angles of a polygon, multiply the number of triangles in the polygon by 180°.
Example
Calculate the sum of interior angles in a pentagon.
A pentagon has 5 sides, so it contains 3 triangles.
The sum of the interior angles is: 180º × 3 = 540∘
The formula for calculating the sum of interior angles is:
(𝑛 − 2) × 180º (where 𝑛 is the number of sides)
If the side of a polygon is extended, the angle formed outside the polygon is the exterior angle. The sum of the exterior angles of a polygon is 360°.
The formula for calculating the size of an exterior angle is 360 divided by the number of sides
Example
This pentagon has 5 sides. To calculate the exterior angles, divide 360º by the number of sides
360º / 5 = 72º
Triangles are 2D shapes with three sides. There are four different triangles with different properties.
3 sides of different lengths
3 unequal angles.
2 sides of equal length
The dashes on the lines show they are equal in length
The angles at the base of the equal sides are equal.
3 sides of equal length.
The dashes on the lines show they are equal in length
All of the angles are equal.
A triangle that has a right angle
Letters can be used to label angles.
AB and AC are line segments, and they meet at point A.
Line segment: a line with 2 endpoints
AB joins the points A and B.
The angle between AB and AC is labelled BAC.
The angle can written as BAC or BÂC or ∠BAC.
The angles inside a shape are called interior angles.
If the side of a triangle is extended, the angle formed outside the triangle is the exterior angle.
g = interior angle
h = exterior angle
g + h = 180º
The interior angle and its corresponding exterior angle always add up to 180°.
The sum of interior angles in a triangle is 180°.
To prove 𝑎 + 𝑏 + 𝑐 = 180º, draw a line parallel to one side of the triangle.
𝑑 = 𝑏 (alternate angles are equal)
𝑒 = 𝑐 (alternate angles are equal)
𝑎 + 𝑑 + 𝑒 = 180º (angles on a straight line add up to 180°)
So 𝑎 + 𝑏 + 𝑐 = 180º
These facts can be used to calculate angles.
Triangles are congruent if they are identical in size and shape. This means all corresponding sides and angles are equal.
RHS: RIGHT ANGLE, HYPOTENUSE, SIDE
Both have right angles
Both have the same hypotenuse length
Both have one other pair of sides which are equal
ASA: ANGLE, SIDE, ANGLE
2 pairs of angles are equal
The side between the angles are the same
SAS: SIDE, ANGLE, SIDE
2 pairs of sides are equal
The angle between the pair of equal sides is the same
SSS: SIDE, SIDE, SIDE
All three pairs of sides are equal
Applies to right-angled triangles
States that the square of the length of the hypotenuse (c) is equal to the sum of the squares of the lengths of the other two sides (a and b).
a, b, and c are the lengths of the three sides
a2 + b2 = c2
Given: A right-angled triangle with legs a = 3 cm and b = 4 cm.
Find: The hypotenuse c
c2 = a2 + b2
= 32 + 42
= 9 + 16 = 25
c2 = 25 cm
Square root both sides = 25 → 5 cm
Circle theorems are properties that show relationships between angles within the geometry of a circle.
The angle that lies between a tangent and a chord is equal to the angle subtended by the same chord in the alternate segment.
How to use it:
Locate the key parts of the circle for the theorem
Use other angle facts to determine one of the two angles
Use the alternate segment theorem to state the other missing angle
The angle at the centre is twice the angle at the circumference.
How to use the fact that the angle at the centre is twice the angle at the circumference:
Locate the key parents of the circle for the theorem
Determine the angle at the centre or the angle at the circumference
Use the angle at the centre to state the other missing angle
Angles in the same segment are equal.
How to use the fact that angles in the same segment are equal
Locate the key parts of the circle for the theorem.
Use other angle facts to determine an angle at the circumference in the same segment.
Use the angle in the same segment theorem to state the other missing angle.
The angle in a semicircle is 90 degrees
How to use the fact that angles in a semicircle equal 90º
Locate the key parts of the circle for the theorem.
Use other angle facts to determine angles within the triangle.
Use the angles in a semicircle theorem to state the other missing angle.
The perpendicular from the centre of a circle to a chord bisects the chord (splits the chord into two equal parts).
How to find missing lengths using chords
Locate the key parts of the circle for an appropriate circle theorem.
Use other angle facts to determine any missing angles.
Use Pythagoras’ theorem or trigonometry to find the missing length.
The angle between a tangent and radius is 90 degrees. Tangents which meet at the same point are equal in length.
How to use the tangent of a circle theorems:
Locate the key parts of the circle for the theorem.
Use other angle facts to determine the remaining angle(s) made with the tangent.
Use the tangent theorem to state the other missing angle.
The opposite angles in a cyclic quadrilateral total 180º
How to use the cyclic quadrilateral theorem
Locate the key parts of the circle for the theorem.
Use other angle facts to determine one of the two opposing angles in the quadrilateral.
Use the cyclic quadrilateral theorem to state the other missing angle.
