Starter Sketch a regular pentagon

Slides:

Advertisements

Similar presentations

Powerpoint hosted on Please visit for 100’s more free powerpoints.

Advertisements

Trigonometry Solving Triangles ADJ OPP HYP  Two old angels Skipped over heaven Carrying a harp Solving Triangles.

Solving Problems Modelled by Triangles. PYTHAGORAS Can only occur in a right angled triangle Pythagoras Theorem states: hypotenuse right angle e.g. square.

Find hypotenuse length in a triangle EXAMPLE 1

Starter a 6 c A 49° 96° 1.Use the Law of Sines to calculate side c of the triangle. 2.Now find the Area of a Triangle.

13-5 The Law of Sines Warm Up Lesson Presentation Lesson Quiz

Trigonometrical rules for finding sides and angles in triangles which are not right angled.

Geometry Notes Lesson 5.3B Trigonometry

The Cosine Rule. AB C a b c a 2 =b2b2 +c2c2 -2bccosA o.

The Cosine Rule. AB C a b c a 2 =b2b2 +c2c2 -2bccosA o.

There are three ratios that you need to learn: Where are the hypotenuse, adjacent and opposite lengths. This is opposite the right-angle This is next to.

Slide The Pythagorean Theorem and the Distance Formula  Special Right Triangles  Converse of the Pythagorean Theorem  The Distance Formula: An.

Pythagoras Theorem a2 + b2 = c2

Topic 1 Pythagorean Theorem and SOH CAH TOA Unit 3 Topic 1.

C2: Trigonometrical Equations Learning Objective: to be able to solve simple trigonometrical equations in a given range.

Applied to non-right angled triangles 1. Introduction In Sec 2,you have learnt to apply the trigonometric ratios to right angled triangles. 2 A hyp adj.

Lesson 5-3 (non honors) The Law of Sines

Solving Right Triangles

Unit 34 Pythagoras’ Theorem and Trigonometric Ratios Presentation 1Pythagoras’ Theorem Presentation 2Using Pythagoras’ Theorem Presentation 3Sine, Cosine.

Area and the Law of Sines. A B C a b c h The area, K, of a triangle is K = ½ bh where h is perpendicular to b (called the altitude). Using Right Triangle.

13-5 The Law of Sines Warm Up Lesson Presentation Lesson Quiz

M May Pythagoras’ Theorem The square on the hypotenuse equals the sum of the squares on the other two sides.

OBJECTIVE I will use the Pythagorean Theorem to find missing sides lengths of a RIGHT triangle.

Similar Triangles and Pythagorean Theorem Section 6.4.

Pythagoras c² a² b² c a b c² = a² + b² has the same area as the two smaller squares added together. The large square + PYTHAGORAS THEOREM is applied to.

Objective: To apply the Law of Cosines for finding the length of a missing side of a triangle. Lesson 18 Law of Cosines.

Math 20-1 Chapter 1 Sequences and Series 2.3B The Ambiguous Case of the Sine Law The Sine Law State the formula for the Law of Sines. What specific.

We are now going to extend trigonometry beyond right angled triangles and use it to solve problems involving any triangle. 1.Sine Rule 2.Cosine Rule 3.Area.

Note 8– Sine Rule The “Ambiguous Case”

H) select and use appropriate trigonometric ratios and formulae to solve problems involving trigonometry that require the use of more than one triangle.

Right Triangle The sides that form the right angle are called the legs. The side opposite the right angle is called the hypotenuse.

Chapter 17: Trigonometry

Starter A triangular pyramid is made from baked bean tins

Trigonometry The word trigonometry comes from the Greek meaning ‘triangle measurement’. Trigonometry uses the fact that the side lengths of similar triangles.

The Law of SINES.

The Sine Rule The Cosine Rule

hypotenuse opposite adjacent Remember

Warm-Up Exercises ABC Find the unknown parts of A = 75°, B 82°, c 16

Starter I think of a number, add 7 and then double it. The answer is 28. What was the original number? I think of another number, subtract 3 and then divide.

Starter Jane is 40. Chris is 10. Chris is ¼ of Jane’s age.

The graph of sin θ Teacher notes Trace out the shape of the sine curve and note its properties. The curve repeats itself every 360°. Also, –1 < sin.

TRIGONOMETRY 2.4.

Chapter 10: Applications of Trigonometry and Vectors

Introduction The distance formula can be used to find solutions to many real-world problems. In the previous lesson, the distance formula was used to.

Right-angled triangles A right-angled triangle contains a right angle. The longest side opposite the right angle is called the hypotenuse. Teacher.

We are Learning to…… Use Angle Facts.

a 2 = b 2 + c b c cos A These two sides are repeated.

We are Learning to…… Use The Cosine Law.

We are Learning to…… Use The Sine Law.

Starter Construct accurately two different triangles with sides 3 cm and 5 cm and an angle of 30° opposite the 3 cm side Use a ruler, protractor and compasses.

Pythagorean Theorem a²+ b²=c².

Objectives Determine the area of a triangle given side-angle-side information. Use the Law of Sines to find the side lengths and angle measures of a triangle.

Day 101 – Area of a triangle.

Starter Work out the missing lengths for these squares and cuboids

Pythagoras' Theorem.

Day 103 – Cosine rules.

Law of Cosines C a b A B c.

Geometry Section 7.7.

The Theorem Of Pythagoras.

The Cosine Rule. A B C a b c a2 = b2 + c2 -2bccosAo.

Completing the Square pages 544–546 Exercises , – , –2

Labelling a Triangle In a general triangle, the vertices are labelled with capital letters. B A C B A C The angles at each vertex are labelled with that.

The Cosine Rule. A B C a b c a2 = b2 + c2 -2bccosAo.

Chapter 2 Trigonometry 2.3 The Sine Law Pre-Calculus 11.

THE SINE RULE Powerpoint hosted on

Presentation transcript:

Starter Sketch a regular pentagon Join each vertex to every other vertex with a straight line How many different sized triangles can you find?

We are Learning to…… Use The Cosine Law

The cosine law Consider any triangle ABC. If we drop a perpendicular line, h from C to AB, we can divide the triangle into two right-angled triangles, ACD and BDC. C b a h A B a is the side opposite A and b is the side opposite B. x D c – x We call the perpendicular h for height (not h for hypotenuse). c is the side opposite C. If we call the length AD x, then the length BD can be written as c – x.

The cosine law Using Pythagoras’ theorem in triangle ACD, C b2 = x2 + h2 1 b a h Also, cos A = x b A B x D c – x x = b cos A 2 In triangle BCD, a2 = (c – x)2 + h2 We call the perpendicular h for height (not h for hypotenuse). To derive the cosine rule we use both Pythagoras’ Theorem and the cosine ratio. a2 = c2 – 2cx + x2 + h2 a2 = c2 – 2cx + x2 + h2 Substituting and , 1 2 This is the cosine law. a2 = c2 – 2cb cos A + b2 a2 = b2 + c2 – 2bc cos A

The cosine law For any triangle ABC, A B C c a b a2 = b2 + c2 – 2bc cos A or cos A = b2 + c2 – a2 2bc We can use the first form of the formula to find side lengths and the second form of the equation to find angles.

Using the cosine law to find side lengths If we are given the length of two sides in a triangle and the size of the angle between them, we can use the cosine law to find the length of the other side. For example, Find the length of side a. B C A 7 cm 4 cm 48° a a2 = b2 + c2 – 2bc cos A The angle between two sides is often called the included angle. We can express the cosine rule as, “the square of the unknown side is equal to the sum of the squares of the other two sides minus 2 times the product of the other two sides and the cosine of the included angle”. Warn pupils not to forget to find the square root. The answer should look sensible considering the other lengths. Advise pupils to keep the value for a2 on their calculator displays. They should square root this value rather than the rounded value that has been written down. This will avoid possible errors in rounding. Point out that if we are given the lengths of two sides and the size of an angle that is not the included angle, we can still use the cosine rule to find the length of the other side. In this case we can either rearrange the formula or substitute the given values and solve an equation. a2 = 72 + 42 – 2 × 7 × 4 × cos 48° a2 = 27.53 (to 2 d.p.) a = 5.25 cm (to 2 d.p.)

Using the cosine law to find side lengths Be aware that the lengths of the sides and the angles have been rounded. This means that, for example, the three angles in the triangle may not add up to exactly 180°. Change the shape of the triangle by dragging on the vertices. Reveal the lengths of two of the sides and the angle between them. Ask a volunteer to show how the cosine rule can be used to find the length of the third side. Make the problem more difficult by revealing two sides and an angle other than the one between them.

Using the cosine law to find angles If we are given the lengths of all three sides in a triangle, we can use the cosine law to find the size of any one of the angles in the triangle. For example, Find the size of the angle at A. 4 cm 8 cm 6 cm A B C cos A = b2 + c2 – a2 2bc cos A = 42 + 62 – 82 2 × 4 × 6 Point out that if the cosine of an angle is negative, we expect the angle to be obtuse. This is because the cosine of angles in the second quadrant is negative. We do not have the same ambiguity as with the sine rule where the sine of angles in both the first and second quadrants are positive and so two solutions between 0° and 180° exist. Angles in a triangle can only be within this range. This is negative so A must be obtuse. cos A = –0.25 A = cos–1 –0.25 A = 104.48° (to 2 d.p.)

Using the cosine law to find angles Be aware that the lengths of the sides and the angles have been rounded. This means that, for example, the three angles in the triangle may not add up to exactly 180°. Change the shape of the triangle by dragging on the vertices. Reveal the lengths of all three sides. Ask a volunteer to show how the cosine rule can be used to find the size of a required angle.

McGraw Hill Page 110 #1 – 6 BLM 2.8 #s 1 – 4 To succeed at this lesson today you need to… 1. Use this when the problem involves three sides and an angle 2. It works for all types of triangle 3. The law is: a² = b² + c² - 2bcCOSA McGraw Hill Page 110 #1 – 6 BLM 2.8 #s 1 – 4

Homework McGraw Hill Page 110 #s 7 – 11 BLM 2.8 #s 5 – 8