Bicycle ramps made for competition (see Figure 1) must vary in height depending on the skill level of the competitors. For advanced competitors, the angle formed by the ramp and the ground should be [latex]θ[/latex] such that [latex]tan[/latex] [latex]θ[/latex] = [latex]\frac{5}{3}[/latex]. The angle is divided in half for novices. What is the steepness of the ramp for novices? In this section, we will investigate three additional categories of identities that we can use to answer questions such as this one.

Using Double-Angle Formulas to Find Exact Values

In the previous section, we used addition and subtraction formulas for trigonometric functions. Now, we take another look at those same formulas. The double-angle formulas are a special case of the sum formulas, where [latex]α[/latex] = [latex]β[/latex]. Deriving the double-angle formula for sine begins with the sum formula,

If we let [latex]α[/latex] = [latex]β[/latex] = [latex]θ[/latex], then we have

Deriving the double-angle for cosine gives us three options. First, starting from the sum formula, [latex]cos[/latex] ([latex]α[/latex] + [latex]β[/latex]) = [latex]cos[/latex] [latex]α[/latex] [latex]cos[/latex] [latex]β[/latex] − [latex]sin[/latex] [latex]α[/latex] [latex]sin[/latex] [latex]β[/latex], and letting [latex]α[/latex] = [latex]β[/latex] = [latex]θ[/latex], we have

Using the Pythagorean properties, we can expand this double-angle formula for cosine and get two more interpretations. The first one is:

The second interpretation is:

Similarly, to derive the double-angle formula for tangent, replacing [latex]α[/latex] = [latex]β[/latex] = [latex]θ[/latex] in the sum formula gives:

Using Double-Angle Formulas to Verify Identities

Establishing identities using the double-angle formulas is performed using the same steps we used to derive the sum and difference formulas. Choose the more complicated side of the equation and rewrite it until it matches the other side.

Use Reduction Formulas to Simplify an Expression

The double-angle formulas can be used to derive the reduction formulas, which are formulas we can use to reduce the power of a given expression involving even powers of sine or cosine. They allow us to rewrite the even powers of sine or cosine in terms of the first power of cosine. These formulas are especially important in higher-level math courses, calculus in particular. Also called the power-reducing formulas, three identities are included and are easily derived from the double-angle formulas.

We can use two of the three double-angle formulas for cosine to derive the reduction formulas for sine and cosine. Let’s begin with [latex]cos (2θ) = 1 − 2 sin^2[/latex] [latex]θ[/latex]. Solve for [latex]sin^2[/latex] [latex]θ[/latex]:

Next, we use the formula [latex]cos[/latex] ([latex]2θ[/latex]) = 2 [latex]cos^2[/latex] [latex]θ[/latex] − 1. Solve for [latex]cos^2[/latex] [latex]θ[/latex]:

The last reduction formula is derived by writing tangent in terms of sine and cosine:

Using Half-Angle Formulas to Find Exact Values

The next set of identities is the set of half-angle formulas, which can be derived from the reduction formulas and we can use when we have an angle that is half the size of a special angle. If we replace [latex]θ[/latex] with [latex]\frac{α}{2}[/latex], the half-angle formula for sine is found by simplifying the equation and solving for [latex]sin[/latex] ([latex]\frac{α}{2}[/latex]). Note that the half-angle formulas are preceded by a ± sign. This does not mean that both the positive and negative expressions are valid. Rather, it depends on the quadrant in which [latex]\frac{α}{2}[/latex] terminates.

The half-angle formula for sine is derived as follows:

To derive the half-angle formula for cosine, we have

For the tangent identity, we have

Media

Access these online resources for additional instruction and practice with double-angle, half-angle, and reduction formulas.

• Double-Angle Identities
• Half-Angle Identities

Section Exercises

Verbal

1. Explain how to determine the reduction identities from the double-angle identity [latex]cos[/latex] ([latex]2x[/latex]) = [latex]cos^2[/latex] [latex]x[/latex] − [latex]sin^2[/latex] [latex]x[/latex].

2. Explain how to determine the double-angle formula for [latex]tan[/latex] ([latex]2x[/latex]) using the double-angle formulas for [latex]cos[/latex] ([latex]2x[/latex]) and [latex]sin[/latex] ([latex]2x[/latex]).

3. We can determine the half-angle formula for [latex]tan[/latex] ([latex]\frac{x}{2}[/latex]) = [latex]\frac{1 − cos x}{1 + cos x}[/latex] by dividing the formula for [latex]sin[/latex] ([latex]\frac{x}{2}[/latex]) by [latex]cos[/latex] ([latex]\frac{x}{2}[/latex]). Explain how to determine two formulas for [latex]tan[/latex] ([latex]\frac{x}{2}[/latex]) that do not involve any square roots.

4. For the half-angle formula given in the previous exercise for [latex]tan[/latex] ([latex]\frac{x}{2}[/latex]), explain why dividing by 0 is not a concern. (Hint: examine the values of [latex]cos[/latex] [latex]x[/latex] necessary for the denominator to be 0)

Algebraic

For the following exercises, find the exact values of a) [latex]sin[/latex] ([latex]2x[/latex]), b) [latex]cos[/latex] ([latex]2x[/latex]), and c) [latex]tan[/latex] ([latex]2x[/latex]) without solving for [latex]x[/latex].

5. If [latex]sin[/latex] [latex]x[/latex] = [latex]\frac{1}{8}[/latex], and [latex]x[/latex] is in quadrant I.

6. If [latex]cos[/latex] [latex]x[/latex] = [latex]\frac{2}{3}[/latex] and [latex]x[/latex] is in quadrant I.

7. If [latex]cos[/latex] [latex]x[/latex] = −[latex]\frac{1}{2}[/latex] and [latex]x[/latex] is in quadrant III.

8. If [latex]tan[/latex] [latex]x[/latex] = = −8, and [latex]x[/latex] is in quadrant IV.

For the following exercises, find the values of the six trigonometric functions if the conditions provided hold.

9. [latex]cos[/latex] ([latex]2θ[/latex]) = [latex]\frac{3}{5}[/latex] and 90° ≤ [latex]θ[/latex] ≤ 180°

10. [latex]cos[/latex] ([latex]2θ[/latex]) = [latex]\frac{1}{2}[/latex] and 180° ≤ [latex]θ[/latex] ≤ 270°

For the following exercises, simplify to one trigonometric expression.

11. 2 [latex]sin[/latex] ([latex]\frac{π}{4}[/latex]) 2 [latex]cos[/latex] ([latex]\frac{π}{4}[/latex])

12. 4 [latex]sin[/latex] ([latex]\frac{π}{8}[/latex]) [latex]cos[/latex] ([latex]\frac{π}{8}[/latex])

For the following exercises, find the exact value using half-angle formulas.

13. [latex]sin[/latex] ([latex]\frac{π}{8}[/latex])

14. [latex]cos[/latex] (−[latex]\frac{11π}{12}[/latex])

15. [latex]sin[/latex] ([latex]\frac{11π}{12}[/latex])

16. [latex]cos[/latex] ([latex]\frac{7π}{8}[/latex])

17. [latex]tan[/latex] ([latex]\frac{5π}{12}[/latex])

18. [latex]tan[/latex] (−[latex]\frac{3π}{12}[/latex])

19. [latex]tan[/latex] (−[latex]\frac{3π}{8}[/latex])

For the following exercises, find the exact values of a) [latex]sin[/latex] ([latex]\frac{x}{2}[/latex]), b) [latex]cos[/latex] ([latex]\frac{x}{2}[/latex]), and c) [latex]tan[/latex] ([latex]\frac{x}{2}[/latex]) without solving for [latex]x[/latex], when 0° ≤ [latex]x[/latex] ≤ 360°

20. If [latex]tan[/latex] [latex]x[/latex] = −[latex]\frac{4}{3}[/latex], and [latex]x[/latex] is in quadrant IV.

21. If [latex]sin[/latex] [latex]x[/latex] = −[latex]\frac{12}{13}[/latex], and [latex]x[/latex] is in quadrant IV.

22. If [latex]csc[/latex] [latex]x[/latex] = 7, and [latex]x[/latex] is in quadrant IV.

23. If [latex]sec[/latex] [latex]x[/latex] = −4, and [latex]x[/latex] is in quadrant IV.

For the following exercises, use Figure 5 to find the requested half and double angles.

24. Find [latex]sin[/latex] ([latex]2θ[/latex]), [latex]cos[/latex] ([latex]2θ[/latex]) and [latex]tan[/latex] ([latex]2θ[/latex]).

25. Find [latex]sin[/latex] ([latex]2α[/latex]), [latex]cos[/latex] ([latex]2α[/latex]), and [latex]tan[/latex] ([latex]2α[/latex])

26. Find [latex]sin[/latex] ([latex]{θ}{2}[/latex]), [latex]cos[/latex] ([latex]{θ}{2}[/latex]), and [latex]tan[/latex] ([latex]{θ}{2}[/latex]).

27. Find [latex]sin[/latex] ([latex]\frac{α}{2}[/latex]), [latex]cos[/latex] ([latex]\frac{α}{2}[/latex]), and [latex]tan[/latex] ([latex]\frac{α}{2}[/latex]).

For the following exercises, simplify each expression. Do not evaluate.

28. [latex]cos^2[/latex] (28°) − [latex]sin^2[/latex] (28°)

29. 2 [latex]cos^2[/latex] (37°) − 1

30. 1 − 2 [latex]sin^2[/latex] (17°)

31. [latex]cos^2[/latex] ([latex]9x[/latex]) − [latex]sin^2[/latex] ([latex]9x[/latex])

32. 4 [latex]sin[/latex] ([latex]8x[/latex]) [latex]cos[/latex] ([latex]8x[/latex])

33. 6 [latex]sin[/latex] ([latex]5x[/latex]) [latex]cos[/latex] ([latex]5x[/latex])

For the following exercises, prove the identity given.

34. ([latex]sin[/latex] [latex]t[/latex] − [latex]cos[/latex] [latex]t[/latex])² = 1− [latex]sin[/latex] ([latex]2t[/latex])

35. [latex]sin[/latex] ([latex]2x[/latex]) = −2 [latex]sin[/latex] (−[latex]x[/latex]) [latex]cos[/latex] (−[latex]x[/latex])

36. [latex]cot[/latex] [latex]x[/latex] − [latex]tan[/latex] [latex]x[/latex] = 2 [latex]cot[/latex] ([latex]2x[/latex])

37. [latex]\frac{1 + cos (2θ)}{sin (2θ)}[/latex] [latex]tan^2[/latex] [latex]θ[/latex] = [latex]tan[/latex] [latex]θ[/latex]

For the following exercises, rewrite the expression with an exponent no higher than 1.

38. [latex]cos^2[/latex] ([latex]5x[/latex])

39. [latex]cos^2[/latex] ([latex]6x[/latex])

40. [latex]sin^4[/latex] ([latex]8x[/latex])

41. [latex]sin^4[/latex] ([latex]3x[/latex])

42. [latex]cos^2[/latex] [latex]x[/latex] [latex]sin^4[/latex] [latex]x[/latex]

43. [latex]cos^4[/latex] [latex]x[/latex] [latex]sin^2[/latex] [latex]x[/latex]

44. [latex]tan^2[/latex] [latex]x[/latex] [latex]sin^2[/latex] [latex]x[/latex]

Extensions

For the following exercises, prove the identities.

45. [latex]sin[/latex] ([latex]2x[/latex]) =  [latex]\frac{2 tan x}{1 + tan^2 x}[/latex]

46. [latex]cos[/latex] ([latex]2α[/latex]) = [latex]\frac{1 − tan^2 α}{1 + tan^2 α}[/latex]

47. [latex]tan[/latex] ([latex]2x[/latex]) =  [latex]\frac{2 sin x cos x}{2 cos^2 x − 1}[/latex]

48. ([latex]sin^2[/latex] [latex]x[/latex] − 1)² = [latex]cos[/latex] ([latex]2x[/latex]) + [latex]sin^4[/latex] [latex]x[/latex]

49. [latex]sin[/latex] ([latex]3x[/latex]) = 3 [latex]sin[/latex] [latex]x[/latex] [latex]cos^2[/latex] [latex]x[/latex] − [latex]sin^3[/latex] [latex]x[/latex]

50. [latex]cos[/latex] ([latex]3x[/latex]) = [latex]cos^3[/latex] [latex]x[/latex] − 3 [latex]sin^2[/latex] [latex]x[/latex] [latex]cos[/latex] [latex]x[/latex]

51. [latex]\frac{1 + cos (2t)}{sin (2t) − cos t}[/latex] = [latex]\frac{2 cos t}{2 sin t − 1}[/latex]

52. [latex]sin[/latex] ([latex]16x[/latex]) =16 [latex]sin[/latex] [latex]x[/latex] [latex]cos[/latex] [latex]x[/latex] [latex]cos[/latex] ([latex]2x[/latex]) [latex]cos[/latex] ([latex]4x[/latex]) [latex]cos[/latex] ([latex]8x[/latex])

53. [latex]cos[/latex] ([latex]16x[/latex]) = ([latex]cos^2[/latex] ([latex]4x[/latex]) − [latex]sin^2[/latex] ([latex]4x[/latex]) − [latex]sin[/latex] ([latex]8x[/latex]))([latex]cos^2[/latex] ([latex]4x[/latex]) − [latex]sin^2[/latex] ([latex]4x[/latex]) + [latex]sin[/latex] ([latex]8x[/latex]))