Presentation is loading. Please wait.

Presentation is loading. Please wait.

Copyright © Cengage Learning. All rights reserved.

Similar presentations


Presentation on theme: "Copyright © Cengage Learning. All rights reserved."— Presentation transcript:

1 Copyright © Cengage Learning. All rights reserved.
7 Analytic Trigonometry Copyright © Cengage Learning. All rights reserved.

2 7.2 Addition and Subtraction Formulas
Copyright © Cengage Learning. All rights reserved.

3 Objectives Addition and Subtraction Formulas
Evaluating Expressions Involving Inverse Trigonometric Functions Expressions of the form A sin x + B cos x

4 Addition and Subtraction Formulas

5 Addition and Subtraction Formulas
We now derive identities for trigonometric functions of sums and differences.

6 Example 1 – Using the Addition and Subtraction Formulas
Find the exact value of each expression. (a) cos 75 (b) cos Solution: (a) Notice that 75 = 45 + 30. Since we know the exact values of sine and cosine at 45 and 30, we use the Addition Formula for Cosine to get cos 75 = cos (45 + 30) = cos 45 cos 30 – sin 45 sin 30 =

7 Example 1 – Solution cont’d (b) Since the Subtraction Formula for Cosine gives cos = cos = cos cos sin sin

8 Example 3 – Proving a Cofunction Identity
Prove the cofunction identity cos = sin u. Solution: By the Subtraction Formula for Cosine we have cos = cos cos u + sin sin u = 0  cos u + 1  sin u = sin u

9 Addition and Subtraction Formulas
The cofunction identity in Example 3, as well as the other cofunction identities, can also be derived from the following figure. The next example is a typical use of the Addition and Subtraction Formulas in calculus. cos = = sin u

10 Example 5 – An identity from Calculus
If f (x) = sin x, show that Solution: Definition of f Addition Formula for Sine

11 Example 5 – Solution cont’d Factor Separate the fraction

12 Evaluating Expressions Involving Inverse Trigonometric Functions

13 Evaluating Expressions Involving Inverse Trigonometric Functions
Expressions involving trigonometric functions and their inverses arise in calculus. In the next examples we illustrate how to evaluate such expressions.

14 Example 6 – Simplifying an Expression Involving Inverse Trigonometric Functions
Write sin(cos–1 x + tan–1 y) as an algebraic expression in x and y, where –1  x  1 and y is any real number. Solution: Let  = cos–1x and  = tan–1y. We sketch triangles with angles  and  such that cos = x and tan  = y (see Figure 2). cos  = x tan  = y Figure 2

15 Example 6 – Solution From the triangles we have
cont’d From the triangles we have sin  = cos  = sin  = From the Addition Formula for Sine we have sin(cos–1 x + tan–1 y) = sin( + ) = sin  cos  + cos  sin  Addition Formula for Sine

16 Example 6 – Solution cont’d From triangles Factor

17 Expressions of the Form A sin x + B cos x

18 Expressions of the Form A sin x + B cos x
We can write expressions of the form A sin x + B cos x in terms of a single trigonometric function using the Addition Formula for Sine. For example, consider the expression sin x cos x If we set  =  /3, then cos  = and sin  = /2, and we can write sin x cos x = cos  sin x + sin  cos x = sin(x + ) = sin

19 Expressions of the Form A sin x + B cos x
We are able to do this because the coefficients and /2 are precisely the cosine and sine of a particular number, in this case,  /3. We can use this same idea in general to write A sin x + B cos x in the form k sin(x + ). We start by multiplying the numerator and denominator by to get A sin x + B cos x =

20 Expressions of the Form A sin x + B cos x
We need a number  with the property that cos  = and sin  = Figure 4 shows that the point (A, B) in the plane determines a number  with precisely this property. Figure 4

21 Expressions of the Form A sin x + B cos x
With this  we have A sin x + B cos x = (cos  sin x + sin  cos x) = sin(x + ) We have proved the following theorem.

22 Example 8 – A Sum of Sine and Cosine Terms
Express 3 sin x + 4 cos x in the form k sin(x + ). Solution: By the preceding theorem, k = = = 5. The angle  has the property that sin  = = and cos  = = , and  in Quadrant I (because sin  and cos  are both positive), so  = sin –1 . Using a calculator, we get   53.1. Thus 3 sin x + 4 cos x  5 sin (x )

23 Example 9 – Graphing a Trigonometric Function
Write the function f (x) = –sin 2x cos 2x in the form k sin(2x + ), and use the new form to graph the function. Solution: Since A = –1 and B = , we have k = = = 2. The angle  satisfies cos  = – and sin  = /2. From the signs of these quantities we conclude that  is in Quadrant II.

24 Example 9 – Solution Thus  = 2 /3.
cont’d Thus  = 2 /3. By the preceding theorem we can write f (x) = –sin 2x cos 2x = 2 sin Using the form f (x) = 2 sin 2

25 Example 9 – Solution cont’d We see that the graph is a sine curve with amplitude 2, period 2 /2 = , and phase shift – /3. The graph is shown in Figure 5. Figure 5


Download ppt "Copyright © Cengage Learning. All rights reserved."

Similar presentations


Ads by Google