Angles
Angles are formed by the intersection of 2 lines, 2 rays, or 2 line segments.
The point at which the lines, rays, or line segments intersect is called the vertex.
Vertex
Vertex
Vertex
Measuring Angles
The measure of an angle is the amount of rotation in degrees about the vertex from one side to the other.
The measure of any angle is between 0º and 180º.
The wider the “mouth,” the greater the measure of the angle.
Classifying Angles
There are 4 types of angles:acute angle – angle that is greater than 0° and less than 90°right angle – angle that is exactly 90°obtuse angle – angle that is greater than 90° and less than 180°straight angle – angle that is exactly 180°
Naming Angles
Angles are named according to their vertex and the points through which each side passes.
Angles can be labeled by only the letter or number that represents their vertex.
If more than 1 angle share a vertex, then label the angle with the points on each side of the angle and the vertex. Make sure that the vertex is always the middle letter.
Homework
Complete all of the problems on “PPF Practice Problems 1.” Also, answer the following questions:
What do acute people and acute angles have in common?
What do obtuse people and obtuse angles have in common?
Angle Addition Postulate
When more than 1 angle share a vertex, the sum of the measure of the smaller angles equal the measure of the largest angle.
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Example 1
17714037WVUm
Angle Relationships
Adjacent Angles – two angles that are next to each other
Complementary Angles – two adjacent angles that form a right angle
Supplementary Angles – two adjacent angles that form a straight angle
Vertical Angles – two angles that are opposite of each other when two lines cross
More Angle Relationships
The following relationships are formed when a transversal line intersects two parallel lines:Corresponding Angles – two angles that are on the same side of the transversal line, but one is inside and the other is outside of the parallel linesAlternate Exterior Angles – two angles that are on opposite sides of the transversal line, but both are outside of the parallel linesAlternate Interior Angles – two angles that are on opposite sides of the transversal line, but both are inside of the parallel linesConsecutive (Co-interior) Angles – two angles that are on the same side of the transversal line and are both inside of the parallel lines
More Info On Angle Relationships
Complementary Angles – add up to 90°Supplementary Angles – add up to 180°Vertical Angles – have the same measureAlternate Exterior Angles – have the same
measureAlternate Interior Angles – have the same
measureCorresponding Angles – have the same
measureConsecutive Angles – add up to 180°
Basic Facts About Triangles
• Three-sided polygon• Each “corner” is a vertex (vertices for
plural)• The area of a triangle is ½ · base · height• The angles in a triangle add up to 180°• Triangles are named by their vertices• Triangles are classified by their sides and
angles
Classifying Triangles by Angles
Acute Triangle – all 3 angles are acute
Right Triangle – has 1 right angle
Obtuse Triangle – has 1 obtuse angle
Classifying Triangles by Sides
Equilateral Triangle – all sides and all angles are congruent
Isosceles Triangle – 2 sides are congruent and base angles are congruent
Scalene Triangle – no sides are congruent
Classifying Triangles by Angles and Sides
Right Scalene
Right Isosceles
Obtuse Scalene
Obtuse Isosceles
Acute Scalene
Acute Isosceles
Triangle Angle Sum
The measure of the unknown angle is 180° – (81° + 58°) = 41°
The measure of the unknown angle is 180° – (90° + 40°) = 50°
Triangle Angle Sum Extended
This angle is also 102° due to the property of vertical angles
This angle is 180° – (102° + 52°) = 26°
The measure of the unknown angle is 180° – 26° = 154° due to the property of supplementary angles.
Homework
Complete all of the problems on PPF Practice Problems 5 and 6.
For extra credit you may complete the “Additional Triangle Angle Sum Practice Problems” sheet.
Triangle Congruence
• Congruent triangles are exactly the same size (same side lengths and angle measures)
• Corresponding sides are the congruent sides of congruent triangles
• Corresponding angles are the congruent angles of congruent triangles
Examples of Congruent Triangles
GHIUVW
STREFD
Note: We must name the congruent triangles correctly according to the corresponding angles!
Proving Triangle Congruence
SSS (side-side-side) – if all 3 pairs of corresponding sides are congruent, then the triangles are congruent
SAS (side-angle-side) – if 2 pairs of corresponding sides and the pair of corresponding angles between them are congruent, then the triangles are congruent
ASA (angle-side-angle) – if 2 pairs of corresponding angles and the pair of corresponding sides between them are congruent, then the triangles are congruent
AAS (angle-angle-side) – if 2 pairs of corresponding angles and the pair of corresponding sides not between them are congruent, then the triangles are congruent
Proving Right Triangle Congruence
LA (leg-angle) – if a pair of corresponding legs and a pair of corresponding angles other than the right angles are congruent, then the right triangles are congruent
LL (leg-leg) – if 2 pairs of corresponding legs are congruent, then the right triangles are congruent
HA (hypotenuse-angle) – if the pair of hypotenuses and a pair of corresponding angles other than the right angles are congruent, then the right triangles are congruent
HL (hypotenuse-leg) – if the pair of hypotenuses and a pair of corresponding legs are congruent, then the right triangles are congruent
Homework
Complete all of the problems on PPF Practice Problems 7
For extra credit do Triangle Congruence Additional Practice Problems
Using Properties of Isosceles Triangles to Find Angle Measures
This angle is 124° (supplementary)
This angle is 28° because it is congruent to the other base angle and together they must add up to 56°
This angle is also 28° (vertical)
This angle is 28° (base angles of isosceles)
This angle is 124° (triangle angle sum)
So, by the properties of supplementary angles, angle x is 56°.
Homework
Complete all of the problems on PPF Practice Problems 8.
For extra credit do Properties of Isosceles and Equilateral Triangles Additional Practice Problems.
Triangle Inequality Theorem
Any side of a triangle is always shorter than the sum of the other two sides but greater than the difference between the other two sides.
The shortest side of a triangle is always greater than the difference between the other two sides, and the longest side of a triangle is always less than the sum of the other two sides.
Example of Using The Triangle Inequality Theorem
Example 1 – State whether or not the following three numbers can be lengths of the sides of a triangle: 8, 8, 14
Solution – 1. Check to see if the longest side is less than the sum of the other two sides.14 < 8 + 8 ? Yes2. Check to see if the shortest side is greater than the difference between the other two sides.8 > 14 – 8? Yes
Therefore, these three numbers can be lengths of the sides of a triangle.
You Try: State If The Three Numbers Can Be Lengths of the Sides of a Triangle
1. 13, 16, 202. 2, 12, 223. 4, 11, 15
Finding The Range of Possible Lengths of The Third Side of a Triangle
Example 1 – What is the range of possible values for x, the length of the third side of the triangle, when given the lengths of the other two sides? 10, 13, x
Solution – 1. x must be less than 13 + 10 = 232. x must be greater than 13 – 10 = 3
Therefore, 3 < x < 23.
You Try
1. Find the range of x, the possible lengths of the third side of the triangle, when given the lengths of the other two sides: 9, 13, x
2. Find the range of x, the possible lengths of the third side of the triangle, when given the lengths of the other two sides: 5, 5, x
Homework
Complete all of the problems on PPF Practice Problems 9.
For extra credit do Triangle Inequality Theorem Additional Practice Problems.
Triangle Sides and AnglesThe longer the side, the larger the angle that is across from it.
The larger the angle, the longer the side that is across from it.
You Try1. Order the sides of the triangle from shortest to longest.
2. Order the angles of the triangle from smallest to largest.
3. In ΔSTU, TU = 8 ¼ SU = 8 4/5ST = 9
Order the angles from smallest to largest.
The Pythagorean Theorem
• Only applies to right triangles
• Used to find the unknown side length of any right triangle
• c² = a² + b²• a and b are the legs,
and c is the hypotenuse (the longest side)
• The hypotenuse is always across from the right angle.
a
b
c
16² = x² + 10² 16² - 10² = x²256 – 100 = x² 156 = x² √156 = x 2√39 = x ≈ 12.5
Real-world Application of the Pythagorean Theorem
Ex 1: A ladder that is 13
feet long is placed against a wall such that the base of the ladder is 5 feet from the wall. How many feet above the ground is the top of the ladder?
The Pythagorean Theorem and The Area of Triangle
• The area of a triangle is
½ · base · height• The base and the
height of a right triangle are its legs
Ex 1: Find the area of the triangle
Solution: Step 1 – use the Pythagorean to find the length of the other leg, which is also the height of the triangleStep 2 – plug the values for the base and the height into the formula of the area of triangles.
Homework
Complete all of the problems on PPF Practice Problems 12. Study for quiz.
For extra credit do The Pythagorean Theorem and the Area of a Triangle Additional Practice Problems.
45°-45°-90° Right Triangles
• Also known as right isosceles triangles
• Legs are congruent• Hypotenuse is √2
times longer than the legs
Finding Missing Side Lengths of 45°-45°-90° Right Triangles
Solution - Example 1 – Find the missing side lengths. Leave your answer as a radical in simplest form if possible.
Hint – Since we know the length of the hypotenuse, we must find the length of the legs, which are congruent to one another, by dividing the hypotenuse by √2.
Finding Missing Side Lengths of 45°-45°-90° Right Triangles
Solution - Example 2 – Find the missing side lengths. Leave your answers as radicals in simplest form if possible.
Hint – Since we know the length of one leg, we know the length of the other leg as well because they are congruent. To find the length of the hypotenuse, we must multiply the length of the leg by √2.
Rules To Finding Missing Side Lengths of 45°-45°-90° Right Triangles
Rule 1 – If you know the length of the hypotenuse, then divide it by √2 to find the length of the legs.
Rule 2 – If you know the length of one of the legs, then multiply it by √2 to find the length of the hypotenuse.
You Try
1. Find the missing side lengths. Leave your answer as a radical in simplest form if possible.
2. Find the missing side lengths. Leave your answer as a radical in simplest form if possible.
30°-60°-90° Right Triangles
• The short leg is across from the 30° angle
• The long leg is across from the 60° angle and is √3 times longer than the short leg
• The hypotenuse is 2 times longer than the short leg
Finding the Unknown Side Length of 30°-60°-90° Right Triangles
The length of the short leg is 5.
y is the long leg, so its length is 5√3
x is the hypotenuse, so its length is 5 ∙ 2 = 10
The length of the long leg is √15
y is the short leg, so its length is
√15 / √3 = √5
x is the hypotenuse, so its length is 2√5
Solving Multi-step 30°-60°-90° Right Triangle Problems
Example 1 – Find the unknown side length, x.
Solution – First find the length of the hypotenuse of the triangle on the right, which is also the long leg of the triangle on the left.
9 ∙ 2 = 18
Next, find the length of x, which is the short leg of the triangle on the left.
= ∙ =
18
Solving Multi-step 30°-60°-90° Right Triangle Problems
Example 2 – Find the unknown side length, x.
Solution – First, find the length of the long leg of the triangle on the left, which is also the hypotenuse of the triangle on the right.
Next, find the short leg of the triangle on the right, which is also x.
÷ 2 = ∙ =
9√32
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