1. Trigonometric Review 1.6

2. Unit Circle

3. The six trigonometric functions of a right triangle, with an acute angle , are defined by ratios of two sides of the triangle. The sides of the right triangle are:  the side opposite the acute angle ,  the side adjacent to the acute angle ,  and the hypotenuse of the right triangle. The trigonometric functions are sine, cosine, tangent, cotangent, secant, and cosecant. opp adj hyp θ Trigonometric Functions sin  = cos  = tan  = csc  = sec  = cot  = opp hyp adj hyp adj opp adj

4. Calculate the trigonometric functions for . The six trig ratios are 4 3 5  sin  = tan  = sec  = cos  = cot  = csc  = Example: Six Trig Ratios

5. Geometry of the 45-45-90 triangle Consider an isosceles right triangle with two sides of length 1. 1x 45 The Pythagorean Theorem implies that the hypotenuse is of length.

6. 60 ○ Consider an equilateral triangle with each side of length 2. The perpendicular bisector of the base bisects the opposite angle. The three sides are equal, so the angles are equal; each is 60 . Geometry of the 30-60-90 triangle 22 2 11 30 ○ Use the Pythagorean Theorem to find the length of the altitude,.

7. Graph of the Sine Function To sketch the graph of y = sin x first locate the key points. These are the maximum points, the minimum points, and the intercepts. 0010sin x 0x Then, connect the points on the graph with a smooth curve that extends in both directions beyond the five points. A single cycle is called a period. y x y = sin x

8. Graph of the Cosine Function To sketch the graph of y = cos x first locate the key points. These are the maximum points, the minimum points, and the intercepts. 1001cos x 0x Then, connect the points on the graph with a smooth curve that extends in both directions beyond the five points. A single cycle is called a period. y x y = cos x

9. y x Tangent Function Graph of the Tangent Function 2. range: (– , +  ) 3. period:  4. vertical asymptotes: 1. domain : all real x Properties of y = tan x period: To graph y = tan x, use the identity. At values of x for which cos x = 0, the tangent function is undefined and its graph has vertical asymptotes.

10. Cotangent Function Graph of the Cotangent Function 2. range: (– , +  ) 3. period:  4. vertical asymptotes: 1. domain : all real x Properties of y = cot x y x vertical asymptotes To graph y = cot x, use the identity. At values of x for which sin x = 0, the cotangent function is undefined and its graph has vertical asymptotes.

11. y x Secant Function Graph of the Secant Function 2. range: (– ,–1]  [1, +  ) 3. period:  4. vertical asymptotes: 1. domain : all real x The graph y = sec x, use the identity. Properties of y = sec x At values of x for which cos x = 0, the secant function is undefined and its graph has vertical asymptotes.

12. x y Cosecant Function Graph of the Cosecant Function 2. range: (– ,–1]  [1, +  ) 3. period:  where sine is zero. 4. vertical asymptotes: 1. domain : all real x To graph y = csc x, use the identity. Properties of y = csc x At values of x for which sin x = 0, the cosecant function is undefined and its graph has vertical asymptotes.

13. Graphing a -> amplitude b -> (2*pi)/b -> period c/b -> phase shift (horizontal shift) d -> vertical shift

14. angle of elevation When an observer is looking downward, the angle formed by a horizontal line and the line of sight is called the: Angle of Elevation and Angle of Depression When an observer is looking upward, angle of elevation. the angle formed by a horizontal line and the line of sight is called the: observer object line of sight horizontal observer object line of sight horizontal angle of depression angle of depression. Angle of Elevation and Angle of Depression

15. Example 2: A ship at sea is sighted by an observer at the edge of a cliff 42 m high. The angle of depression to the ship is 16 . What is the distance from the ship to the base of the cliff? The ship is 146 m from the base of the cliff. line of sight angle of depression horizontal observer ship cliff 42 m 16 ○ d Example 2: Application d = = 146.47.

16. Example 3: A house painter plans to use a 16 foot ladder to reach a spot 14 feet up on the side of a house. A warning sticker on the ladder says it cannot be used safely at more than a 60  angle of inclination. Does the painter’s plan satisfy the safety requirements for the use of the ladder? Next use the inverse sine function to find .  = sin  1 (0.875) = 61.044975 The painter’s plan is unsafe! ladder house 16 14 The angle formed by the ladder and the ground is about 61 . θ Example 3: Application sin  = = 0.875

17. Fundamental Trigonometric Identities for 0 <  < 90 . Cofunction Identities sin  = cos(90    ) cos  = sin(90    ) tan  = cot(90    ) cot  = tan(90    ) sec  = csc(90    ) csc  = sec(90    ) Reciprocal Identities sin  = 1/csc  cos  = 1/sec  tan  = 1/cot  cot  = 1/tan  sec  = 1/cos  csc  = 1/sin  Quotient Identities tan  = sin  /cos  cot  = cos  /sin  Pythagorean Identities sin 2  + cos 2  = 1 tan 2  + 1 = sec 2  cot 2  + 1 = csc 2  Pg. 51 & 52

18. Trig Identities

19. Homework READ section 1.6 – IT WILL HELP!! Pg. 57 # 1 - 75 odd