LESSON 5–5

1. LESSON 5–5 Multiple-Angle and Product-to-Sum Identities

2. Five-Minute Check (over Lesson 5-4) TEKS Then/Now Key Concept: Double-Angle Identities and Proof: Double-Angle Identity for Sine Example 1: Evaluate Expressions Involving Double Angles Example 2: Solve an Equation Using a Double-Angle Identity Key Concept: Power-Reducing Identities and Proof: Power-Reducing Identity for Sine Example 3: Use an Identity to Reduce a Power Example 4: Solve an Equation Using a Power-Reducing Identity Key Concept: Half-Angle Identities and Proof: Half-Angle Identity for Cosine Example 5: Evaluate an Expression Involving a Half Angle Example 6: Solve an Equation Using a Half-Angle Identity Key Concept: Product-to-Sum Identities and Proof: Product-to-Sum Identity for sin α cos β Example 7: Use an Identity to Write a Product as a Sum or Difference Key Concept: Sum-to-Product Identities and Proof: Sum-to-Product Identity for sin α + sin β Example 8: Use a Product-to-Sum or Sum-to-Product Identity Example 9: Solve an Equation Using a Sun-to-Product Identity Lesson Menu

3. A. B. C. D. Find the exact value of sin 75°. 5–Minute Check 1

4. Find the exact value of . A. B. C. D. 5–Minute Check 2

5. Find the exact value of . A. B. C. D. 5–Minute Check 3

6. Simplify . A.tan( + 19°) B.tan19 C.tan(19 )° D. 5–Minute Check 4

7. Find the solution to = 1 in the interval [0, 2). A. B. C. D. 5–Minute Check 5

8. Targeted TEKS P.5(M) Use trigonometric identities such as reciprocal, quotient, Pythagorean, cofunctions, even/odd, and sum and difference identities for cosine and sine to simplify trigonometric Mathematical Processes P.1(A), P.1(D) TEKS

9. You used sum and difference identities. (Lesson 5-4) • Use double-angle, power-reducing, and half-angle identities to evaluate trigonometric expressions and solve trigonometric equations. • Use product-to-sum identities to evaluate trigonometric expressions and solve trigonometric equations. Then/Now

10. Key Concept 1

11. If on the interval , find sin 2θ, cos 2θ, and tan 2θ. Since on the interval , one point on the terminal side of θ has y-coordinate 3 and a distance of 4 units from the origin, as shown. Evaluate Expressions Involving Double Angles Example 1

12. The x-coordinate of this point is therefore or . Using this point, we find that cos θ = and tan θ = . Evaluate Expressions Involving Double Angles Use these values and the double-angle identities for sine and cosine to find sin 2θ and cos 2θ. Then find tan 2θ using either the tangent double-angle identity or the definition of tangent. sin 2θ = 2sin θ cos θ cos2θ = 2cos2θ – 1 Example 1

13. Evaluate Expressions Involving Double Angles Method 1 Example 1

14. Evaluate Expressions Involving Double Angles Method 2 Example 1

15. Answer: Evaluate Expressions Involving Double Angles Example 1

16. If on the interval , find, sin2, cos 2,and tan 2. A. B. C. D. Example 1

17. cos θ = or cos θ = –1 Solve for cos θ. Solve an Equation Using a Double-Angle Identity Solve cos 2θ – cos θ = 2 on the interval [0, 2π]. cos 2θ –cos θ = 2 Original equation 2 cos2θ –1 –cos θ – 2 = 0 Cosine Double-Angle Identity 2 cos2θ– cos θ – 3 = 0 Simplify. (2 cos θ – 3)( cos θ + 1) = 0 Factor. 2 cos θ –3 = 0 or cos θ + 1 = 0 Zero Product Property θ = πSolve for  Example 2

18. Since cos θ = has no solution, the solution on the interval [0, 2π) is θ = π. Solve an Equation Using a Double-Angle Identity Answer:π Example 2

19. A. B. C. D. Solve tan2 + tan = 0 on the interval [0, 2π). Example 2

20. Key Concept 3

21. csc4θ = (csc2θ)2 (csc2θ)2 = csc4θ Reciprocal Identity Pythagorean Identity Cosine Power-Reducing Identity Use an Identity to Reduce a Power Rewrite csc4θ in terms of cosines of multiple angles with no power greater than 1. Example 3

22. Common denominator Simplify. Square the fraction. Cosine Power-Reducing Identity Use an Identity to Reduce a Power Example 3

23. Common denominator Simplify. So, csc4θ = . Answer: Use an Identity to Reduce a Power Example 3

24. A. B. C. D. Rewrite tan4x in terms of cosines of multiple angles with no power greater than 1. Example 3

25. Sine Power-Reducing Identity Multiply each side by 2. Add like terms. Double-Angle Identity Simplify. Solve an Equation Using a Power-Reducing Identity Solve sin2θ+ cos 2θ– cos θ= 0. Solve Algebraically sin2θ+ cos 2θ–cos θ= 0 Original equation Example 4

26. Factor.  =  = 0 Solve for θ on [0, 2π). The graph of y = sin2θ+cos 2θ–cos θ has a period of 2, so the solutions are Solve an Equation Using a Power-Reducing Identity 2cos θ= 0 cos θ – 1 = 0 Zero Product Property cos  = 0 cos  = 1 Solve for cos . Example 4

27. The graph of y = sin2θ+ cos 2θ– cos θ has zeros at on the interval [0, 2π).  Answer: Solve an Equation Using a Power-Reducing Identity Support Graphically Example 4

28. A. B. C. D. Solve cos 2x + 2cos2x = 0. Example 4

29. Key Concept 5

30. Sine Half-Angle Identity (Quadrant I angle) Evaluate an Expression Involving a Half Angle Find the exact value of sin 22.5°. Notice that 22.5° is half of 45°. Therefore, apply the half-angle identity for sine, noting that since 22.5° lies in Quadrant I, its sine is positive. Example 5

31. Subtract and then divide. Quotient Property of Square Roots Answer: Evaluate an Expression Involving a Half Angle Example 5

32. CHECK Use a calculator to support your assertion that sin 22.5° = . sin 22.5° = 0.3826834324 and = 0.3826834324  Evaluate an Expression Involving a Half Angle Example 5

33. Find the exact value of . A. B. C. D. Example 5

34. Solve on the interval [0, 2π). Original equation Sine and Cosine Half-Angle Identities Square each side. 1 – cos x = 1 + cos x Multiply each side by 2. Subtract 1 – cos x from each side. Solve an Equation Using a Half-Angle Identity Example 6

35. Solve for x. The solutions on the interval [0, 2π) are . Answer: Solve for cos x. Solve an Equation Using a Half-Angle Identity Example 6

36. Solve on the interval [0, 2π). A. B. C. D. Example 6

37. Key Concept 7

38. Product-to-Sum Identity Simplify. Distributive Property Answer: Use an Identity to Write a Product as a Sum or Difference Rewrite cos 6x cos 3x as a sum or difference. Example 7

39. A. B. C. D. Rewrite sin 4x cos 2x as a sum or difference. Example 7

40. Key Concept 8

41. Sum-to-Product Identity Simplify. Use a Product-to-Sum or Sum-to-Product Identity Find the exact value of cos 255° + cos 195°. Example 8

42. Simplify. The exact value of cos 255° + cos 195° is . Answer: Use a Product-to-Sum or Sum-to-Product Identity Example 8

43. A. B. C. D. Find the exact value of sin 255° + sin 195°. Example 8

44. Sine Sum-to-Product Identity Simplify. Solve an Equation Using a Sum-to-Product Identity Solve sin 8x – sin 2x = 0. Solve Algebraically sin 8x –sin 2x = 0 Original equation Set each factor equal to zero and find solutions on the interval [0, 2π). Example 9

45. First factor set equal to 0 2cos 5x = 0 Divide each side by 2. Multiple angle solutions in [0, 2π). Divide each solution by 5. Second factor set equal to 0 sin 3x = 0 Multiple angle solutions in [0, 2π). Divide each solution by 3. Solve an Equation Using a Sum-to-Product Identity Example 9

46. The period of y = cos 5x is and the period of y = sin 3x is , so the solutions are where n is an integer. Solve an Equation Using a Sum-to-Product Identity Example 9

47. The graph of y = sin 8x –sin 2x has zeros at on the interval .  Solve an Equation Using a Sum-to-Product Identity Support Graphically Example 9

48. Answer: Solve an Equation Using a Sum-to-Product Identity Example 9

49. A. B. C. D. Solve sin 6x + sin 2x = 0. Example 9

50. LESSON 5–5 Multiple-Angle and Product-to-Sum Identities