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Five-Minute Check (over Lesson 10-5) Then/Now New Vocabulary
Key Concept: Power Series Example 1: Power Series Representation of a Rational Function Key Concept: Exponential Series Example 2: Exponential Series Key Concept: Power Series for Cosine and Sine Example 3: Power Series for Cosine and Sine Key Concept: Euler’s Formula Key Concept: Exponential Form of a Complex Number Example 4: Write a Complex Number in Exponential Form Example 5: Natural Logarithm of a Negative Number Lesson Menu
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Use Pascal’s triangle to expand the binomial (2a + 4b)4.
A. 16a a a a + 256 B. 16a4 + 32a3b + 64a2b ab b4 C. 16a a3b + 384a2b ab b4 D. 16a4 + 32a3b + 24a2b2 + 8ab3 + b4 5–Minute Check 1
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Use Pascal’s triangle to expand the binomial (2a + 4b)4.
A. 16a a a a + 256 B. 16a4 + 32a3b + 64a2b ab b4 C. 16a a3b + 384a2b ab b4 D. 16a4 + 32a3b + 24a2b2 + 8ab3 + b4 5–Minute Check 1
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Use Pascal’s triangle to expand the binomial (2 – y)6.
A. 64 – 192y + 240y 2 – 160y3 + 60y4 – 12y5 + y6 B y + 240y y3 + 60y4 +12y5 + y6 C. 64 – 32y + 16y 2 – 8y3 + 4y4 – 2y5 + y6 D. 64y6 – 192y y 4 – 160y3 + 60y 2 – 12y 5–Minute Check 2
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Use Pascal’s triangle to expand the binomial (2 – y)6.
A. 64 – 192y + 240y 2 – 160y3 + 60y4 – 12y5 + y6 B y + 240y y3 + 60y4 +12y5 + y6 C. 64 – 32y + 16y 2 – 8y3 + 4y4 – 2y5 + y6 D. 64y6 – 192y y 4 – 160y3 + 60y 2 – 12y 5–Minute Check 2
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Find the coefficient of the 5th term in the expansion of (a + b)9.
5–Minute Check 3
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Find the coefficient of the 5th term in the expansion of (a + b)9.
5–Minute Check 3
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Find the coefficient of the x 2y 2 term in the expansion of (3x – y)4.
B. 9 C. 36 D. 54 5–Minute Check 4
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Find the coefficient of the x 2y 2 term in the expansion of (3x – y)4.
B. 9 C. 36 D. 54 5–Minute Check 4
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Which expression represents the expansion of (x – 5)4 using sigma notation?
B. C. D. 5–Minute Check 5
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Which expression represents the expansion of (x – 5)4 using sigma notation?
B. C. D. 5–Minute Check 5
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Use a power series to represent a rational function.
You found the nth term of an infinite series expressed using sigma notation. (Lesson 10-1) Use a power series to represent a rational function. Use power series representations to approximate values of transcendental functions. Then/Now
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power series exponential series Euler’s Formula Vocabulary
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Key Concept 1
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Power Series Representation of a Rational Function
Use to find a power series representation of Indicate the interval on which the series converges. Use a graphing calculator to graph g(x) and the sixth partial sum of its power series. Example 1
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Power Series Representation of a Rational Function
To find the transformation that relates f(x) to g(x), use u-substitution. Substitute u for x in f, equate the two functions, and solve for u as shown. g(x) = f(u) Example 1
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Power Series Representation of a Rational Function
Therefore, g(x) = f(x – 3). Replacing x with x – 3 in f(x) = for |x | < 1 yields for |x – 3| < 1. Therefore, g(x) = can be represented by the power series This series converges for |x – 3| < 1, which is equivalent to –1 < x – 3 < 1 or 2 < x < 4. Example 1
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Power Series Representation of a Rational Function
The sixth partial sum S6(x) of this series is or 1 + (x – 3) + (x – 3)2 + (x – 3)3 + (x – 3)4 + (x – 3)5 . The graphs of g(x) = and S6(x) = 1 + (x – 3) + (x – 3)2 + (x – 3)3 + (x – 3)4 + (x – 3)5 are shown. Notice that on the interval (2, 4), the graph of S6(x) comes close to the graph of g(x). Example 1
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Power Series Representation of a Rational Function
Example 1
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Power Series Representation of a Rational Function
Answer: Example 1
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Answer: g(x) = for 2 < x < 4
Power Series Representation of a Rational Function Answer: g(x) = for 2 < x < 4 Example 1
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Use to find a power series representation of
Use to find a power series representation of Indicate the interval on which the series converges. Use a graphing calculator to graph g(x) and the sixth partial sum of its power series. Example 1
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A. g(x) = for –2 < x < 2;
B. g(x) = for –1 < x < 1; C. g(x) = for < x < ; D. g(x) = for –3 < x < 3; Example 1
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A. g(x) = for –2 < x < 2;
B. g(x) = for –1 < x < 1; C. g(x) = for < x < ; D. g(x) = for –3 < x < 3; Example 1
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Key Concept 2
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Exponential Series Use the fifth partial sum of the exponential series to approximate the value of e1.25. Round to three decimal places. x = 1.25 Simplify. Answer: Example 2
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Exponential Series Use the fifth partial sum of the exponential series to approximate the value of e1.25. Round to three decimal places. x = 1.25 Simplify. Answer: Example 2
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Exponential Series CHECK A calculator, using a partial sum of the exponential series with many more terms, returns an approximation of 3.49 for e1.25.Therefore, an approximation of is reasonable. Example 2
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Use the fifth partial sum of the exponential series to approximate the value of e0.75. Round to three decimal places. A B C D Example 2
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Use the fifth partial sum of the exponential series to approximate the value of e0.75. Round to three decimal places. A B C D Example 2
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Key Concept 2
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Power Series for Cosine and Sine
A. Use the fifth partial sum of the power series for cosine to approximate the value of cos . Round to three decimal places. Example 3
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Power Series for Cosine and Sine
Simplify. Answer: Example 3
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Power Series for Cosine and Sine
Simplify. Answer: CHECK A calculator, using a partial sum of the power series for cosine with many more terms, returns an approximation of for cos .Therefore, an approximation of is reasonable. Example 3
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Power Series for Cosine and Sine
B. Use the fifth partial sum of the power series for sine to approximate the value of sin Round to three decimal places. Example 3
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Power Series for Cosine and Sine
Simplify. Answer: Example 3
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Power Series for Cosine and Sine
Simplify. Answer: CHECK A calculator, using a partial sum of the power series for sine with many more terms, returns an approximation of for sin Therefore, an approximation of is reasonable. Example 3
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Use the fifth partial sum of the power series for sine to approximate the value of sin Round to three decimal places. A B C D Example 3
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Use the fifth partial sum of the power series for sine to approximate the value of sin Round to three decimal places. A B C D Example 3
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Key Concept 4
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Key Concept 4
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Write 1 + i in exponential form.
Write a Complex Number in Exponential Form Write 1 + i in exponential form. Write the polar form of 1 + i. In this expression, a = 1, b = 1, and a > 0. Find r. Simplify. Now find . = tan–1 θ = tan– for a > 0 = Simplify. Example 4
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Therefore, because a + bi = rei, the exponential form of 1 + i is .
Write a Complex Number in Exponential Form Therefore, because a + bi = rei, the exponential form of 1 + i is Answer: Example 4
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Therefore, because a + bi = rei, the exponential form of 1 + i is .
Write a Complex Number in Exponential Form Therefore, because a + bi = rei, the exponential form of 1 + i is Answer: Example 4
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Write 2 + 2i in exponential form.
B. C. D. Example 4
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Write 2 + 2i in exponential form.
B. C. D. Example 4
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ln (–2) = ln 2 + i ln (–k) = ln k + i
Natural Logarithm of a Negative Number Find the value of ln (–2) in the complex number system. ln (–2) = ln 2 + i ln (–k) = ln k + i i Use a calculator to compute ln 2. Answer: Example 5
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ln (–2) = ln 2 + i ln (–k) = ln k + i
Natural Logarithm of a Negative Number Find the value of ln (–2) in the complex number system. ln (–2) = ln 2 + i ln (–k) = ln k + i i Use a calculator to compute ln 2. Answer: i Example 5
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Find the value of ln (–7) in the complex number system.
A i B C i D Example 5
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Find the value of ln (–7) in the complex number system.
A i B C i D Example 5
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End of the Lesson
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