Browse By Unit

Subject

♾️AP Calculus AB/BC

Study Guides by Unit

👑Unit 1 – Limits and Continuity

🤓Unit 2 – Fundamentals of Differentiation

🤙🏽Unit 3 – Composite, Implicit, and Inverse Functions

👀Unit 4 – Contextual Applications of Differentiation

✨Unit 5 – Analytical Applications of Differentiation

🔥Unit 6 – Integration and Accumulation of Change

💎Unit 7 – Differential Equations

🐶Unit 8 – Applications of Integration

🦖Unit 9 – Parametric Equations, Polar Coordinates, and Vector–Valued Functions (BC Only)

♾Unit 10 – Infinite Sequences and Series (BC Only)

Additional Resources

📚Study Tools

✏️Frequently Asked Questions

🤔Exam Skills

🌶️AP Cram Sessions 2021

🌶Live Cram Sessions 2020

🗓️Previous Exam Prep

📚

All Subjects

>

♾️

AP Calc

>

♾

Unit 10

10.7 Alternating Series Test for Convergence

1 min read•june 18, 2024

10.7 Alternating Series Test for Convergence

Welcome to AP Calc 10.7! In this lesson, you’ll how to test for convergence when dealing with an alternating series.

➕ Alternating Series Test Theorem

The alternating series test for convergence states that for an alternating series $\sum(-1)^n\cdot a_n$ , if

1. \lim_{n\to \infty} a_n=0 \ \text{and}

2. \ a_n \ \text{decreases,}

then the series converges. Otherwise, it diverges.

🧱 Breaking Down the Theorem

To illustrate this theorem, let’s look at a famous example—the alternating harmonic sequence:

\sum_{n=1}^\infty\frac{(-1)^n}{n}

Let’s look at our first criteria: the limit of $a_n$ must be equal to zero. To figure this out, we first must figure out what $a_n$ is! To do this, all we have to do is factor out the alternating part of the sequence, $(-1)^n$ . Then, we get

a_n=\frac{1}{n}

Now, let’s take the limit.

\lim_{n\to \infty}\frac{1}{n}=0

Well, that’s our first criteria satisfied! Now we need to know whether $a_n$ decreases. To show this, we must show that $a_n>a_{n+1}$ .

a_n=\frac{1}{n}>\frac{1}{n+1}=a_{n+1}

Try plugging in a random number for $n$ to see that this is true!

a_2=\frac{1}{2}>\frac{1}{3}=a_{2+1}

Therefore, both of our conditions for convergence are met, and our series converges!

📝 Practice with Alternating Series Test

Now it’s your turn to apply what you’ve learned!

❓Alternating Series Test Problems

For each of the following series, state whether they converge or diverge.

1. \sum_{n=1}^\infty \frac{(-1)^{n+2}\cdot n^5}{n^5+3}

2. \sum_{n=2}^\infty\frac{\text{cos}(n\pi)}{n}

3.\sum_{n=2}^\infty (-1)^n \cdot\text{ln}(n)

💡 Alternating Series Test Solutions

Question 1 Solution

First, identify $a_n$ .

a_n=\frac{n^5}{n^5+3}

Now, take the limit.

\lim_{n\to \infty}\frac{n^5}{n^5+3}=1\neq0

Since our first condition isn’t met, we don’t need to check the second condition. This series is divergent.

Question 2 Solution

This one is a little tricky—it requires you to recognize another type of alternating series, $\text{cos}(n\pi)$ . If you plug some examples into your calculator, you’ll see that $\text{cos}(n\pi)=(-1)^n$ . Therefore, we can treat this equation just like the harmonic series in our first example. We showed that the harmonic series met the conditions for convergence, so this one does too! This series is convergent.

Question 3 Solution

First, we find $a_n=\text{ln}(n)$ . Then, we take the limit:

\lim_{n\to \infty}\text{ln}(n)=\infty

Like our first problem, since the first condition isn’t met, we can say that this series is divergent without checking the other condition.

💫 Closing

Great work! With this test mastered, you’re well equipped to take on all sorts of convergence problems. Make sure you recognize both types of alternating series so that you know when to apply this test! 🧠

<< Hide Menu

📚

All Subjects

>

♾️

AP Calc

>

♾

Unit 10

10.7 Alternating Series Test for Convergence

1 min read•june 18, 2024

10.7 Alternating Series Test for Convergence

Welcome to AP Calc 10.7! In this lesson, you’ll how to test for convergence when dealing with an alternating series.

➕ Alternating Series Test Theorem

The alternating series test for convergence states that for an alternating series $\sum(-1)^n\cdot a_n$ , if

1. \lim_{n\to \infty} a_n=0 \ \text{and}

2. \ a_n \ \text{decreases,}

then the series converges. Otherwise, it diverges.

🧱 Breaking Down the Theorem

To illustrate this theorem, let’s look at a famous example—the alternating harmonic sequence:

\sum_{n=1}^\infty\frac{(-1)^n}{n}

Let’s look at our first criteria: the limit of $a_n$ must be equal to zero. To figure this out, we first must figure out what $a_n$ is! To do this, all we have to do is factor out the alternating part of the sequence, $(-1)^n$ . Then, we get

a_n=\frac{1}{n}

Now, let’s take the limit.

\lim_{n\to \infty}\frac{1}{n}=0

Well, that’s our first criteria satisfied! Now we need to know whether $a_n$ decreases. To show this, we must show that $a_n>a_{n+1}$ .

a_n=\frac{1}{n}>\frac{1}{n+1}=a_{n+1}

Try plugging in a random number for $n$ to see that this is true!

a_2=\frac{1}{2}>\frac{1}{3}=a_{2+1}

Therefore, both of our conditions for convergence are met, and our series converges!

📝 Practice with Alternating Series Test

Now it’s your turn to apply what you’ve learned!

❓Alternating Series Test Problems

For each of the following series, state whether they converge or diverge.

1. \sum_{n=1}^\infty \frac{(-1)^{n+2}\cdot n^5}{n^5+3}

2. \sum_{n=2}^\infty\frac{\text{cos}(n\pi)}{n}

3.\sum_{n=2}^\infty (-1)^n \cdot\text{ln}(n)

💡 Alternating Series Test Solutions

Question 1 Solution

First, identify $a_n$ .

a_n=\frac{n^5}{n^5+3}

Now, take the limit.

\lim_{n\to \infty}\frac{n^5}{n^5+3}=1\neq0

Since our first condition isn’t met, we don’t need to check the second condition. This series is divergent.

Question 2 Solution

This one is a little tricky—it requires you to recognize another type of alternating series, $\text{cos}(n\pi)$ . If you plug some examples into your calculator, you’ll see that $\text{cos}(n\pi)=(-1)^n$ . Therefore, we can treat this equation just like the harmonic series in our first example. We showed that the harmonic series met the conditions for convergence, so this one does too! This series is convergent.

Question 3 Solution

First, we find $a_n=\text{ln}(n)$ . Then, we take the limit:

\lim_{n\to \infty}\text{ln}(n)=\infty

Like our first problem, since the first condition isn’t met, we can say that this series is divergent without checking the other condition.

💫 Closing

Great work! With this test mastered, you’re well equipped to take on all sorts of convergence problems. Make sure you recognize both types of alternating series so that you know when to apply this test! 🧠

Fiveable

About Us

About Fiveable Blog Careers Code of Conduct Terms of Use Privacy Policy CCPA Privacy Policy

Resources

Cram Mode Fiveable Library Study Rooms College Hub Study Plans Help Center Merch Shop

Student Wellness

Wellness Guides Joon Care Resources Crisis Text Line International Hotlines

Stay Connected

© 2024 Fiveable Inc. All rights reserved.

About Us

About Fiveable Blog Careers Code of Conduct Terms of Use Privacy Policy CCPA Privacy Policy

Resources

Cram Mode Fiveable Library Study Rooms College Hub Study Plans Help Center Merch Shop

Student Wellness

Wellness Guides Joon Care Resources Crisis Text Line International Hotlines

© 2024 Fiveable Inc. All rights reserved.