Textbook Question
9–36. Comparison tests Use the Comparison Test or the Limit Comparison Test to determine whether the following series converge.
∑ (k = 1 to ∞) ((3k³ + 4)(7k² + 1)) / ((2k³ + 1)(4k³ − 1))
Ch. 10 - Sequences and Infinite Series
Briggs3rd EditionCalculus: Early TranscendentalsISBN: 9780136847243
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Table of contents
- Ch. 1 - Functions210
- Ch. 2 - Limits371
- Ch. 3 - Derivatives633
- Ch. 4 - Applications of the Derivative412
- Ch. 5 - Integration328
- Ch. 6 - Applications of Integration331
- Ch. 7 - Logarithmic, Exponential Functions, and Hyperbolic Functions177
- Ch. 8 - Integration Techniques394
- Ch. 9 - Differential Equations179
- Ch. 10 - Sequences and Infinite Series339
- Ch. 11 - Power Series218
- Ch.12 - Parametric and Polar Curves215
Briggs3rd EditionCalculus: Early TranscendentalsISBN: 9780136847243Not the one you use?Change textbook
Chapter 10, Problem 10.3.17
16–17. {Use of Tech} Periodic savings
Suppose you deposit m dollars at the beginning of every month in a savings account that earns a monthly interest rate of r, which is the annual interest rate divided by 12 (for example, if the annual interest rate is 2.4%, r = 0.024/12 = 0.002). For an initial investment of m dollars, the amount of money in your account at the beginning of the second month is the sum of your second deposit and your initial deposit plus interest, or m + m(1 + r). Continuing in this fashion, it can be shown that the amount of money in your account after n months is
Aₙ = m + m(1 + r) + ⋯ + m(1 + r)ⁿ⁻¹.
Use geometric sums to determine the amount of money in your savings account after 5 years (60 months) using the given monthly deposit and interest rate.
17. Monthly deposits of \$250 at a monthly interest rate of 0.2%
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Identify the variables given in the problem: the monthly deposit amount \(m = 250\), the monthly interest rate \(r = 0.002\) (which is 0.2%), and the total number of months \(n = 60\) (5 years).
Recognize that the total amount in the account after \(n\) months is given by the sum of a geometric series:
\[A_n = m + m(1 + r) + m(1 + r)^2 + \cdots + m(1 + r)^{n-1}.\]
Factor out \(m\) from the sum to write it as:
\[A_n = m \left[1 + (1 + r) + (1 + r)^2 + \cdots + (1 + r)^{n-1}\right].\]
Use the formula for the sum of a geometric series with first term \(a = 1\) and common ratio \(q = 1 + r\):
\[\sum_{k=0}^{n-1} q^k = \frac{q^n - 1}{q - 1}.\]
Substitute \(q = 1 + r\) to get:
\[A_n = m \cdot \frac{(1 + r)^n - 1}{r}.\]
Substitute the known values \(m = 250\), \(r = 0.002\), and \(n = 60\) into the formula to express the amount after 5 years:
\[A_{60} = 250 \cdot \frac{(1 + 0.002)^{60} - 1}{0.002}.\]
This expression can now be evaluated to find the total amount in the account.
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Key Concepts
Here are the essential concepts you must grasp in order to answer the question correctly.
Geometric Series and Sums
A geometric series is a sum of terms where each term is a constant multiple (common ratio) of the previous one. The formula for the sum of the first n terms is Sₙ = a(1 - rⁿ) / (1 - r), where a is the first term and r is the common ratio. This formula helps calculate the total amount accumulated when deposits grow with interest over time.
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Geometric Series
Compound Interest with Periodic Deposits
Compound interest means interest is earned on both the initial principal and the accumulated interest from previous periods. When deposits are made periodically, each deposit grows for a different number of periods, requiring summation of multiple compound amounts. Understanding this helps model how monthly deposits accumulate with interest.
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Converting Annual Interest Rate to Monthly Rate
Interest rates are often given annually but compounding occurs monthly, so the annual rate must be divided by 12 to find the monthly rate. For example, an annual rate of 2.4% becomes 0.002 monthly. This conversion is essential for accurately calculating interest growth in monthly compounding scenarios.
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04:16Intro To Related Rates
Related Practice
Textbook Question
9–16. Divergence Test Use the Divergence Test to determine whether the following series diverge or state that the test is inconclusive.
∑ (k = 0 to ∞) 1 / (1000 + k)
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Textbook Question
32–49. Choose your test Use the test of your choice to determine whether the following series converge absolutely, converge conditionally, or diverge.
∑ (from k = 1 to ∞) k¹⁰⁰ / (k + 1)!
Textbook Question
9–36. Comparison tests Use the Comparison Test or the Limit Comparison Test to determine whether the following series converge.
∑ (k = 1 to ∞) (2 + (−1)ᵏ) / k²
Textbook Question
13–20. Explicit formulas Write the first four terms of the sequence { aₙ }∞ₙ₌₁.
aₙ = 1 + sin(πn / 2)
Textbook Question
Find a formula for the nth partial sum Sₙ of
∑ k = 1 to ∞[(1/(k + 3)) − (1/(k + 4))]
Use your formula to find the sum of the first 36 terms of the series.
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