/*! This file is auto-generated */ .wp-block-button__link{color:#fff;background-color:#32373c;border-radius:9999px;box-shadow:none;text-decoration:none;padding:calc(.667em + 2px) calc(1.333em + 2px);font-size:1.125em}.wp-block-file__button{background:#32373c;color:#fff;text-decoration:none} Problem 68 For the following telescoping se... [FREE SOLUTION] | 91Ó°ÊÓ

91Ó°ÊÓ

Log out

Learning Materials

Features

Discover

Chapter 9: Problem 68

For the following telescoping series, find a formula for the nth term of the sequence of partial sums \(\left\\{S_{n}\right\\} .\) Then evaluate lim \(S_{n}\) to obtain the value of the series or state that the series diverges. \(^{n \rightarrow \infty}\) $$\sum_{k=1}^{\infty}\left(\tan ^{-1}(k+1)-\tan ^{-1} k\right)$$

Short Answer

Expert verified
Answer: The given telescoping series converges, and its value is \(\frac{\pi}{4}\).

Step by step solution

01

Find the series term

The given infinite series can be represented as: $$\sum_{k=1}^{\infty} \left(\tan^{-1}(k+1) - \tan^{-1}(k)\right)$$
02

Representation as partial sums

To translate this representation as partial sums, we have: $$S_n = \sum_{k=1}^{n} \left(\tan^{-1}(k+1) - \tan^{-1}(k)\right)$$
03

Telescoping

Now we will telescope the series by canceling out common terms in consecutive elements of the sum: $$\begin{aligned} S_n &= \left(\tan^{-1}(2) - \tan^{-1}(1)\right) + \left(\tan^{-1}(3) - \tan^{-1}(2)\right) + \cdots + \left(\tan^{-1}(n+1) - \tan^{-1}(n)\right) \\ &= \left(\tan^{-1}(n+1) - \tan^{-1}(1)\right) \end{aligned}$$
04

Find the limit

Now, we want to find the value of the series by evaluating lim \(S_n\) as \(n\) approaches infinity: $$\lim_{n \to \infty} S_n = \lim_{n \to \infty} \left(\tan^{-1}(n+1) - \tan^{-1}(1)\right)$$ Notice that as n goes to infinity, \((n+1)\) grows towards infinity, and \(\tan^{-1}(n+1)\) approaches \(\frac{\pi}{2}\) since the range of the inverse tangent function is from \(-\frac{\pi}{2}\) to \(\frac{\pi}{2}\). Thus, $$\lim_{n \to \infty} S_n = \lim_{n \to \infty} \left(\frac{\pi}{2} - \tan^{-1}(1)\right) = \frac{\pi}{2} - \tan^{-1}(1)$$ Since \(\tan^{-1}(1) = \frac{\pi}{4}\), we get: $$\lim_{n \to \infty} S_n = \frac{\pi}{2} - \frac{\pi}{4} = \frac{\pi}{4}$$ Therefore, the given series converges, and its value is \(\frac{\pi}{4}\).

Unlock Step-by-Step Solutions & Ace Your Exams!

  • Full Textbook Solutions

    Get detailed explanations and key concepts

  • Unlimited Al creation

    Al flashcards, explanations, exams and more...

  • Ads-free access

    To over 500 millions flashcards

  • Money-back guarantee

    We refund you if you fail your exam.

Over 30 million students worldwide already upgrade their learning with 91Ó°ÊÓ!

Key Concepts

These are the key concepts you need to understand to accurately answer the question.

Sequence of Partial Sums
Imagine a series as a long string of numbers added together, an infinite string in this case. When you're working with a telescoping series, like the one given in our exercise, the idea is to find a simpler way to express this long sum. This is where the sequence of partial sums comes into play.

You don't start by tackling the infinite series directly. Instead, you evaluate smaller parts of it, called partial sums. A partial sum, denoted by \(S_n\), is simply the sum of the first \(n\) terms of your series. For example, if you have a series \(a_1 + a_2 + a_3 + \ldots\), the partial sum \(S_3\) would be \(a_1 + a_2 + a_3\).

In the telescoping series given:
  • We express the partial sum \(S_n\) using the series terms from the first term up to the \(n\)-th term.
  • Consequently, for our exercise, \(S_n\) transforms from an infinite sum into a more manageable expression that mirrors the cancellations typical of a telescoping series.
This simplification allows us to see the broader picture of how the sums behave as \(n\) becomes very large.
Inverse Trigonometric Functions
The inverse trigonometric functions play a crucial role in many mathematical expressions, particularly when dealing with series like the one in our exercise. Specifically, we're working with the inverse tangent function, \(\tan^{-1}(x)\), also known as the arctangent function.

The inverse tangent function is the inverse operation of the tangent function, essentially solving for the angle whose tangent is a particular value. It has a unique impact on our series, given its predictable range of values:
  • The range of \(\tan^{-1}(x)\) is from \(-\frac{\pi}{2}\) to \(\frac{\pi}{2}\).
  • This means that as \(x\) increases to positive infinity, the value of \(\tan^{-1}(x)\) approaches \(\frac{\pi}{2}\).

In the context of the telescoping series in this exercise, this property is key because it explains why \(\tan^{-1}(k+1) - \tan^{-1}(k)\) simplifies further when expressed as partial sums. Understanding this function's behavior is critical as it directly influences the limit and convergence of the series as \(n\) approaches infinity.
Series Convergence
Convergence is the term used to describe whether a series approaches a specific value as its terms stretch toward infinity. It answers the essential question: does the series settle down to a particular number?

In the case of our telescoping series, after simplifying the sequence of partial sums with the help of inverse trigonometric functions, the issue of convergence becomes apparent.
  • We calculate the limit of the partial sum \(\lim_{n \to \infty} S_n\).
  • The inverse tangent function's nature aids us, as it guarantees that \(\tan^{-1}(n+1)\) approaches \(\frac{\pi}{2}\) as \(n\) grows indefinitely.

This means the partial sum equation \(\tan^{-1}(n+1) - \tan^{-1}(1)\) ultimately resolves to a fixed number as \(n\) heads toward infinity. The series converges to \(\frac{\pi}{4}\), establishing that our original infinite series isn't merely an accumulation of infinite values—it actually locks onto a precise value, expressing that the sum is stable and predictable over the long run.

One App. One Place for Learning.

All the tools & learning materials you need for study success - in one app.

Get started for free

Most popular questions from this chapter

Consider the series \(\sum_{k=3}^{\infty} \frac{1}{k \ln k(\ln \ln k)^{p}},\) where \(p\) is a real number. a. For what values of \(p\) does this series converge? b. Which of the following series converges faster? Explain. $$ \sum_{k=2}^{\infty} \frac{1}{k(\ln k)^{2}} \text { or } \sum_{k=3}^{\infty} \frac{1}{k \ln k(\ln \ln k)^{2}} ? $$

Suppose a ball is thrown upward to a height of \(h_{0}\) meters. Each time the ball bounces, it rebounds to a fraction r of its previous height. Let \(h_{n}\) be the height after the nth bounce and let \(S_{n}\) be the total distance the ball has traveled at the moment of the nth bounce. a. Find the first four terms of the sequence \(\left\\{S_{n}\right\\}\) b. Make a table of 20 terms of the sequence \(\left\\{S_{n}\right\\}\) and determine a plausible value for the limit of \(\left\\{S_{n}\right\\}.\) $$h_{0}=20, r=0.75$$

Consider the expression \(\sqrt{1+\sqrt{1+\sqrt{1+\sqrt{1+\cdots}}}},\) where the process continues indefinitely. a. Show that this expression can be built in steps using. the recurrence relation \(a_{0}=1, a_{n+1}=\sqrt{1+a_{n}},\) for \(n=0,1,2,3, \ldots .\) Explain why the value of the expression can be interpreted as \(\lim _{n \rightarrow \infty} a_{n}\). b. Evaluate the first five terms of the sequence \(\left\\{a_{n}\right\\}\). c. Estimate the limit of the sequence. Compare your estimate with \((1+\sqrt{5}) / 2,\) a number known as the golden mean. d. Assuming the limit exists, use the method of Example 5 to determine the limit exactly. e. Repeat the preceding analysis for the expression \(\sqrt{p+\sqrt{p+\sqrt{p+\sqrt{p+\cdots}}}}\) where \(p > 0 .\) Make a table showing the approximate value of this expression for various values of \(p .\) Does the expression seem to have a limit for all positive values of \(p ?\)

The expression where the process continues indefinitely, is called a continued fraction. a. Show that this expression can be built in steps using the recurrence relation \(a_{0}=1, a_{n+1}=1+1 / a_{n},\) for \(n=0,1,2,3, \ldots . .\) Explain why the value of the expression can be interpreted as \(\lim a_{n}\). b. Evaluate the first five terms of the sequence \(\left\\{a_{n}\right\\}\). c. Using computation and/or graphing, estimate the limit of the sequence. d. Assuming the limit exists, use the method of Example 5 to determine the limit exactly. Compare your estimate with \((1+\sqrt{5}) / 2,\) a number known as the golden mean. e. Assuming the limit exists, use the same ideas to determine the value of where \(a\) and \(b\) are positive real numbers.

Consider the following sequences defined by a recurrence relation. Use a calculator, analytical methods, and/or graphing to make a conjecture about the value of the limit or determine that the limit does not exist. $$a_{n+1}=\frac{1}{2}\left(a_{n}+2 / a_{n}\right) ; a_{0}=2, n=0,1,2, \dots$$
See all solutions

Recommended explanations on Math Textbooks

Calculus

Read Explanation

Statistics

Read Explanation

Probability and Statistics

Read Explanation

Mechanics Maths

Read Explanation

Applied Mathematics

Read Explanation

Geometry

Read Explanation
View all explanations

What do you think about this solution?

We value your feedback to improve our textbook solutions.

Study anywhere. Anytime. Across all devices.