Presentation is loading. Please wait.

Presentation is loading. Please wait.

1 1 1 2 *Special Angles 45° 60° 30° 30°, 45°, and 60° → common reference angles Memorize their trigonometric functions. Use the Pythagorean Theorem;

Published byPeregrine Peters Modified over 9 years ago

Similar presentations

Presentation on theme: "1 1 1 2 *Special Angles 45° 60° 30° 30°, 45°, and 60° → common reference angles Memorize their trigonometric functions. Use the Pythagorean Theorem;"— Presentation transcript:

1

2

3 1 1 1 2 *Special Angles 45° 60° 30° 30°, 45°, and 60° → common reference angles Memorize their trigonometric functions. Use the Pythagorean Theorem; triangles below.

4 1 2 *Special Angles 60° 30° 30°, 45°, and 60° → common reference angles Memorize their trigonometric functions. Use the Pythagorean Theorem; triangles below.

5 1 1 *Special Angles 45° 30°, 45°, and 60° → common reference angles Memorize their trigonometric functions. Use the Pythagorean Theorem; triangles below.

6 * Special Angles θ 0º 30º 45º 60º 90º sin θ cos θ tan θ

7 RECIPROCAL TRIG FUNCTIONS SIN  CSC  COS  SEC  TAN  COT 

8 RECIPROCAL TRIG FUNCTIONS SIN  CSC  COS  SEC  TAN  COT 

9 Find trig functions of 300° without calculator. Reference angle is 60°[360°  300°]; IV quadrant 300° 60° sin 300° = cos 300° = tan 300° = csc 300° = sec 300° = cot 300° = Use special angle chart.

10 Find trig functions of 120° without calculator. Reference angle is 120°[180°  120°]; IIquadrant sin 120° = cos 120° = tan 120° = csc 120° = sec 120° = cot 120° = Use special angle chart. 60°

11 Find trig functions of 210° without calculator. Reference angle is [210°-180°]; III quadrant 60° sin 210° = cos 210° = tan 210° = csc 210° = sec 210° = cot 210° = Use special angle chart.

12 sin 300° = cos 300° = tan 300° = csc 300° = sec 300° = cot 300° =

13

14 12*Quadrant Angles Reference angles cannot be drawn for quadrant angles 0°, 90°, 180°, and 270° Determined from the unit circle; r = 1 Coordinates of points (x, y) correspond to (cos θ, sin θ)

15 0° (1,0) 180° (  1,0) *Quadrant Angles 90° (0,1) → (cos θ, sin θ) 270° (0,  1) r = 1

16 *Quadrant Angles θ 0º 90º 180º 270º sin θ cos θ tan θ 0 0

17 Find trig functions for  90°. Reference angle is (360°  90°) → 270° sin 270° = cos 270° = tan 270°= csc 270° = sec 270°= cot 270° = 270°  90° Use quadrant angle chart.

18

19 *Coterminal Angle θ 1 = 405º The angle between 0º and 360º having the same terminal side as a given angle. Ex. 405º  360º = coterminal angle 45º θ 2 = 45º

20 *Coterminal Angles Example cos 900° = (See quadrant angles chart) Used with angles greater than 360°, or angles less than 0°.

21 Example tan (  135° ) = (See special angles chart)

22 Find the value of sec 7π / 4 SOLUTION

23

24 Express as a function of the reference angle and find the value. tan 210°sec 120 ° SOLUTION

25 Express as a function of the reference angle and find the value. csc 225° sin (  330°) SOLUTION

26 Express as a function of the reference angle and find the value. cos (  5π) cot (9π/2) SOLUTION

27 SINCOSTANSECCSCCOT 0 30 45 60 90

28

29 Inverse Trig Functions Used to find the angle when two sides of right triangle are known... or if its trigonometric functions are known Notation used: Read: “angle whose sine is …” Also,

30 Inverse trig functions have only one principal value of the angle defined for each value of x:  90° < arcsin < 90° 0° < arccos < 180°  90° < arctan < 90°

31 Example: Given tan θ =  1.600, find θ to the nearest 0.1° for 0° < θ < 360° Tan is negative in II & IV quadrants

32 θ = 180°  58.0° = 122° II θ = 360°  58.0° = 302° IV Note: On the calculator entering results in  58.0°

33

34 Given sin θ = , find θ to the nearest 0.1° for 0° < θ < 360° SOLUTION

35 Given cos θ =  0.0157, find θ to the nearest 0.1° for 0° < θ < 360° SOLUTION

36 Given sec θ = 1.553 where sin θ < 0, find θ to the nearest 0.1° for 0° < θ < 360° SOLUTION

37 Given the terminal side of θ passes through point (2, -1), find θ the nearest tenth for 0° < θ < 360° SOLUTION

38 Given the terminal side of θ passes through point (3, 5), find θ the nearest tenth for 0° < θ < 360° SOLUTION

39 Given the terminal side of θ passes through point (8, 8), find θ the nearest tenth for 0° < θ < 360° SOLUTION

40 Given the terminal side of θ passes through point (-5, 12), find θ the nearest tenth for 0° < θ < 360° SOLUTION

41

42

43

44

45 The voltage of ordinary house current is expressed as V = 170 sin 2πft, where f = frequency = 60 Hz and t = time in seconds. Find the angle 2πft in radians when V = 120 volts and 0 < 2πft < 2π SOLUTION

46 Find t when V = 120 volts SOLUTION

47 The angle β of a laser beam is expressed as: where w = width of the beam (the diameter) and d = distance from the source. Find β if w = 1.00m and d = 1000m. SOLUTION

Download ppt "1 1 1 2 *Special Angles 45° 60° 30° 30°, 45°, and 60° → common reference angles Memorize their trigonometric functions. Use the Pythagorean Theorem;"

Similar presentations

Determining signs of Trig Functions (Pos/Neg)

Determining signs of Trig Functions (Pos/Neg)
Section 5.3 Trigonometric Functions on the Unit Circle

Section 5.3 Trigonometric Functions on the Unit Circle
7.4 Trigonometric Functions of General Angles

7.4 Trigonometric Functions of General Angles
Day 2 and Day 3 notes. 1.4 Definition of the Trigonometric Functions OBJ:  Evaluate trigonometric expressions involving quadrantal angles OBJ:  Find.

Day 2 and Day 3 notes. 1.4 Definition of the Trigonometric Functions OBJ:  Evaluate trigonometric expressions involving quadrantal angles OBJ:  Find.
Day 3 Notes. 1.4 Definition of the Trigonometric Functions OBJ:  Evaluate trigonometric expressions involving quadrantal angles OBJ:  Find the angle.

Day 3 Notes. 1.4 Definition of the Trigonometric Functions OBJ:  Evaluate trigonometric expressions involving quadrantal angles OBJ:  Find the angle.
1.5 Using the Definitions of the Trigonometric Functions OBJ: Give the signs of the six trigonometric functions for a given angle OBJ: Identify the quadrant.

1.5 Using the Definitions of the Trigonometric Functions OBJ: Give the signs of the six trigonometric functions for a given angle OBJ: Identify the quadrant.
Section 5.2 Trigonometric Functions of Real Numbers Objectives: Compute trig functions given the terminal point of a real number. State and apply the reciprocal.

Section 5.2 Trigonometric Functions of Real Numbers Objectives: Compute trig functions given the terminal point of a real number. State and apply the reciprocal.
Trig Functions of Special Angles

Trig Functions of Special Angles
The Trigonometric Functions What about angles greater than 90°? 180°? The trigonometric functions are defined in terms of a point on a terminal side r.

The Trigonometric Functions What about angles greater than 90°? 180°? The trigonometric functions are defined in terms of a point on a terminal side r.
Trigonometry/Precalculus ( R )

Trigonometry/Precalculus ( R )
13.3 Evaluating Trigonometric Functions

13.3 Evaluating Trigonometric Functions
Chapter 14 Day 5 Trig Functions of Any Angle.  We can also evaluate trig functions of an angle that contains a point that isn’t necessarily on the unit.

Chapter 14 Day 5 Trig Functions of Any Angle.  We can also evaluate trig functions of an angle that contains a point that isn’t necessarily on the unit.
9.3 Evaluate Trigonometric Functions of Any Angle

9.3 Evaluate Trigonometric Functions of Any Angle
7.3 Trigonometric Functions of Angles. Angle in Standard Position Distance r from ( x, y ) to origin always (+) r ( x, y ) x y  y x.

7.3 Trigonometric Functions of Angles. Angle in Standard Position Distance r from ( x, y ) to origin always (+) r ( x, y ) x y  y x.
Trigonometric Functions on the

Trigonometric Functions on the
Chapter 5 Review. 1.) If there is an angle in standard position of the measure given, in which quadrant does the terminal side lie? Quad III Quad IV Quad.

Chapter 5 Review. 1.) If there is an angle in standard position of the measure given, in which quadrant does the terminal side lie? Quad III Quad IV Quad.
5.2-1 5.2Trigonometric Functions Let (x, y) be a point other then the origin on the terminal side of an angle  in standard position. The distance from.

Trigonometric Functions Let (x, y) be a point other then the origin on the terminal side of an angle  in standard position. The distance from.
Sum and Difference Formulas Section 5.4. Exploration:  Are the following functions equal? a) Y = Cos (x + 2)b) Y = Cos x + Cos 2 How can we determine.

Sum and Difference Formulas Section 5.4. Exploration:  Are the following functions equal? a) Y = Cos (x + 2)b) Y = Cos x + Cos 2 How can we determine.
Circular Trigonometric Functions.

Circular Trigonometric Functions.
4-3: Trigonometric Functions of Any Angle What you’ll learn about ■ Trigonometric Functions of Any Angle ■ Trigonometric Functions of Real Numbers ■ Periodic.

4-3: Trigonometric Functions of Any Angle What you’ll learn about ■ Trigonometric Functions of Any Angle ■ Trigonometric Functions of Real Numbers ■ Periodic.

Similar presentations

Ads by Google