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Copyright © 2009 Pearson Addison-Wesley Double-Angle Identities 5.5 Double-Angle Identities ▪ An Application ▪ Product-to-Sum and Sum-to-Product Identities
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Copyright © 2009 Pearson Addison-Wesley 5.5-1
5Trigonometric Identities
Copyright © 2009 Pearson Addison-Wesley 5.5-2
5.1 Fundamental Identities
5.2 Verifying Trigonometric Identities
5.3 Sum and Difference Identities for Cosine
5.4 Sum and Difference Identities for Sine and Tangent
5.5 Double-Angle Identities
5.6 Half-Angle Identities
5 Trigonometric Identities
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5.5-3
Double-Angle Identities5.5Double-Angle Identities ▪ An Application ▪ Product-to-Sum and Sum-to-Product Identities
Copyright © 2009 Pearson Addison-Wesley 5.5-4
Double-Angle Identities
We can use the cosine sum identity to derive double-angle identities for cosine.
Cosine sum identity
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Double-Angle Identities
There are two alternate forms of this identity.
Copyright © 2009 Pearson Addison-Wesley 5.5-6
Double-Angle Identities
We can use the sine sum identity to derive a double-angle identity for sine.
Sine sum identity
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Double-Angle Identities
We can use the tangent sum identity to derive a double-angle identity for tangent.
Tangent sum identity
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Double-Angle Identities
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Example 1 FINDING FUNCTION VALUES OF 2θ GIVEN INFORMATION ABOUT θ
Given and sin θ < 0, find sin 2θ, cos 2θ, and tan 2θ.
The identity for sin 2θ requires sin θ.
Any of the three forms may be used.
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Example 1 FINDING FUNCTION VALUES OF 2θ GIVEN INFORMATION ABOUT θ (cont.)
Now find tan θ and then use the tangent double-angle identity.
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Example 1 FINDING FUNCTION VALUES OF 2θ GIVEN INFORMATION ABOUT θ (cont.)
Alternatively, find tan 2θ by finding the quotient of sin 2θ and cos 2θ.
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Example 2 FINDING FUNCTION VALUES OF θ GIVEN INFORMATION ABOUT 2θ
Find the values of the six trigonometric functions of θ if
Use the identity to find sin θ:
θ is in quadrant II, so sin θ is positive.
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Example 2 FINDING FUNCTION VALUES OF θ GIVEN INFORMATION ABOUT 2θ (cont.)
Use a right triangle in quadrant II to find the values of cos θ and tan θ.
Use the Pythagorean theorem to find x.
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Example 3 VERIFYING A DOUBLE-ANGLE IDENTITY
Quotient identity
Verify that is an identity.
Double-angle identity
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Example 4 SIMPLIFYING EXPRESSION DOUBLE-ANGLE IDENTITIES
Simplify each expression.
Multiply by 1.
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Example 5 DERIVING A MULTIPLE-ANGLE IDENTITY
Write sin 3x in terms of sin x.
Sine sum identity
Double-angle identities
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where V is the voltage and R is a constant that measure the resistance of the toaster in ohms.*
Example 6 DETERMINING WATTAGE CONSUMPTION
If a toaster is plugged into a common household outlet, the wattage consumed is not constant. Instead it varies at a high frequency according to the model
*(Source: Bell, D., Fundamentals of Electric Circuits, Fourth Edition, Prentice-Hall, 1988.)
Graph the wattage W consumed by a typical toaster with R = 15 and in the window [0, .05] by [–500, 2000]. How many oscillations are there?
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Example 6 DETERMINING WATTAGE CONSUMPTION
There are six oscillations.
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Product-to-Sum Identities
The identities for cos(A + B) and cos(A – B) can be added to derive a product-to-sum identity for cosines.
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Product-to-Sum Identities
Similarly, subtracting cos(A + B) from cos(A – B) gives a product-to-sum identity for sines.
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Product-to-Sum Identities
Using the identities for sin(A + B) and sine(A – B) gives the following product-to-sum identities.
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Product-to-Sum Identities
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Example 7
Write 4 cos 75° sin 25° as the sum or difference of two functions.
USING A PRODUCT-TO-SUM IDENTITY
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Sum-to-Product Identities
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Example 8
Write as a product of two functions.
USING A SUM-TO-PRODUCT IDENTITY
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