<< Hide Menu
Welcome to AP Calc 10.6! In this lesson, you’ll how to test for convergence by comparing your function to an easier one!
In calculus, we use comparison tests when we are dealing with a series that is too complicated to determine the convergence of directly. There are two types of comparison tests, so we’ll break them both down here!
The Direct Comparison Test states that for two series, and where and ,
(1) converges if converges and
(2) diverges if .
Let’s think this through for a second and put it in plain English! We have two series, both of which have to be positive ( is our first condition). Our first function must be smaller than our second function ( is our second condition). If our larger series converges, then a smaller one must also converge. Likewise, if our smaller series diverges, a larger series must also diverge.
We’ll get into when this test is appropriate to use in the examples!
Sometimes we can’t directly compare a function to another one. For these scenarios, we use an indirect method—the Limit Comparison Test, which states that for two series, and where both series either **converge or diverge if is positive and finite.
Let’s break this down! Similarly to the first comparison test, we have two series that are positive. But, we’re not directly comparing in this case. Instead, we’re comparing end behavior of our two functions. If our limit of was zero, it would mean that grew much fast than (it would have to grow to ). If the limit was , then would’ve had to grow much faster to outpace . But, if we have a positive, finite value (like , for example), then the two functions behave similarly and we can compare them—basically, if one converges, so does the other and if one diverges, so does the second one.
Let’s dig in to some examples so we can understand these tests better!
Let’s try a few examples.
(1) Determine if the following series converges.
Without a comparison test, we wouldn’t have the tools to solve this.
If you said direct, you’d be correct! We can compare this series to
We can make this comparison because both functions from the series are positive, and (this is because ). Using the p-series test, we know that converges, so we know that our series also converges!
Let’s try one more to practice the limit comparison test!
(2) Determine if the following series converges.
This means that
We will try comparing to
We need to find the limit of the ratio between the two functions, like so:
Since 1 is positive and finite, we can compare these two series. And, since we know converges using the geometric series test, then our series also converges!
Now that you know the basics, try some out on your own!
Determine whether the following series converge or diverge.
For this, we’ll apply the limit comparison test, comparing to
Then, we take the limit:
Applying L’Hopital’s Rule, we get that the limit is equal to 1. Thus, we can compare the two series. We can apply the p-series test to our second series to find that it diverges. Thus, our original series also diverges.
For this, we will use a limit comparison test. We can compare it to
Then, we take the limit:
Applying L’Hopital’s again, we find that the limit is equal to 1. Thus, we can compare these two series. Since our comparison series is the harmonic series, which we know diverges, we conclude that our original series also diverges.
For this problem, we can use a direct comparison test with . This is true because for all values of , so
for all values of . We use the p-series test to find that converges, therefore, our original series also converges.
Great work! Make sure to keep practicing picking between these two tests and build a toolkit of series to compare to. With all of that done, you’ll ace any comparison tests you come across 💯
© 2024 Fiveable Inc. All rights reserved.