The ratio test allows for proving convergence or divergence of many explicitly given series, so it is among the most popular criteria in use. Although it is applicable to fewer series than the root test, proofs based on the ratio test are usually easier to do.

The ratio test was first published by mathematician and physicist Jean-Baptiste le Rond d’Alembert and is thus sometimes called d'Alembert's ratio test.

Derivation

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First thoughts

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Similar to the root test, the ratio test makes use of the direct comparison test to reduce the convergence of the series in question to that of a geometric series. Let   be a given series with   for all  . The requirement of non-negative summands is necessary for the direct comparison test. We know that the series converges, if there is some   such that   for all  . This follows immediately from direct comparison to the geometric series  , which converges for  .

The root test simply transforms the inequality   to  . The ratio test instead employs a recursive argument with   as an implication. As a starting point, we require   (so the inequality holds for the base case  ). To prove the target inequality for all   by induction, we would need a criterion allowing to deduce   from the inductive assumption  . Assuming  , we find

 

where we used that  , as a ratio of non-negative numbers, is itself non-negative. Since we already assumed  , the set of series for which the ratio test is applicable reduces to those with   for all  .

As a consequence, to deduce   from the inductive assumption it suffices to have  . In turn, a sufficient condition for this to hold is the simple recursive relation

 

Summarizing our first thoughts

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Assuming  , we can show inductively that   and   together imply   for all  . This statement is a direct comparison with a geometric series. Such series converge for  , and so does the series in question, if all criteria are met. Given the base case   and inductive assumption  , the inductive step reads:

 

First improvement

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Whether a series converges or diverges does not depend on finitely many of its summands, as convergence is a property of the infinite. That means, if we take a convergent series and change a finite number of its summands, we obtain another convergent series (though with a possibly different value). Hence one could expect the requirement   to be irrelevant for the convergence of the entire series, as it only affects a single summand.

In fact, assuming only   we find

 

Altogether, we have  . The series   is proportional to a convergent geometric series, so it is itself convergent. By direct comparison, we have thus shown convergence of the series   using   alone, without any restrictions to  .

Second improvement

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We can generalize our induction proof even further by not only dropping our special requirement for  , but also the quotient requirement for a finite number of pairs of subsequent summands. In mathematical terms: We require   only for almost all  . After that, we are still left with an infinite number of pairs for which the requirement holds. In particular, we can find some  , such that the criterion still holds for all  . Beyond this index we have a similar situation as before:

 

Altogether we have   for all  . After an index shift   the inequality reads   for all  . We can now find a finite upper estimate for the whole series:

 

This proves convergence of the series by direct comparison. Hence, it is successful to require   only for almost all  .

Rephrasing in terms of limit superior

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The condition   for almost all   and some fixed   with   can be expressed using the notion of limit superior. In fact, the statement of the previous phrase is equivalent to  .

We prove equivalence by starting with the first statement.   for almost all   implies that all cluster points of the sequence   must be smaller than or equal to  . In particular, the limit superior, which is the greatest cluster point, then must obey  , which is the second statement.

Now for the converse direction. Let  . Then for any   the inequality   holds for almost all  . Since  , we can choose   small enough such that also  , e.g.  . If we now set  , we have both   and   for almost all  . Given the second statement, we can thus explicitly construct a   for which the first statement holds.

We can summarize that   is a sufficient criterion for the series   to converge.

Adding a flavor of absolute convergence

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So far, we restricted ourselves to series with non-negative summands. Can we extend our convergence criterion to general series with (at least some) negative summands?

For any given series  , we can construct another series  , whose summands are clearly non-negative. This series is now in the range of applicability for our ratio test. However, showing convergence for that series is exactly what it means to show absolute convergence for the original series. As we have seen before, absolute convergence implies "common" convergence.

If  , then the series   is absolutely convergent, and hence convergent.

Introduction of the absolute value changes nothing for series whose summands have been non-negative already (the situation we assumed so far). Thus, the new version of the ratio test introduced in this section is strictly more powerful than the one we considered before, as it has a larger range of applicability and absolute convergence is a stronger statement than convergence.

Ratio test for divergence

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Is it possible to prove the divergence of a series with a similar argument? Let's look at  . If the (absolute value of the) quotient is greater than or equal to one, then

 

Thus, if starting from any index   for all subsequent indices   the inequality   is satisfied, then the sequence   grows monotonically, starting from the index  . This sequence cannot be a zero sequence, because it grows monotonically after the sequence member   and  . But if   is not a zero sequence, then   is not a zero sequence either. It follows, according to the term test, that the series   is not a zero sequence. After all, the term test states that   would hold if the series   was convergent. To summarise:

If   holds for almost all   , then   is not a null sequence. The series   diverges by the term test.

The ratio test

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Explanation of the ratio test. (YouTube video (in German) by the channel Quatematik)

Theorem (Ratio test for divergence)

Let   be a series with   for all  . If  , then the series   is absolutely convergent.

If   holds for almost all   (that is, for all   for a given  ), then the series   is divergent.

We summarise the above derivation in a proof:

Proof (Ratio test for divergence)

Let   be a series with non-zero summands.

Proof step: Ratio test for convergence

Let  . We now choose   so small that  . Because of   this   exists (for example,   can be chosen). From the properties of the limit superior it follows that for almost all   the inequality   is satisfied. So there is a natural number   such that   for all  . Hence:

 

Altogether, we obtain  . By setting  , the inequality   follows and thus:

 

So the series   converges according to the direct comparison test. This in turn means that   converges absolutely.

Proof step: Ratio test for divergence

Now let   be a natural number such that   for almost all  . Then for all   there is:

 

Thus the sequence   grows monotonically starting from the index  . The sequence   is not zero because   (as  ). But this means that   is also not a zero sequence. From the term test it follows that the series   diverges.

Stronger statement by the limes inferior

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The condition for divergence which we just discussed can be tightened using the limes inferior. This makes the criterion easier to apply. If  , it follows that   for almost all  . So the series diverges. The converse does not always hold true. From   for almost all   we cannot imply  , since the sequence   does not necessarily have a smallest accumulation point. It is therefore a stronger condition for the divergence of the series.

Hint

If  , then there exists a   with   for almost all  , so the series converges absolutely. Similarly, the series diverges if  .

Limits of the ratio test

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For   we cannot say anything about convergence or divergence of the series. There are in fact both convergent and divergent series that fulfil this condition. An example of this is the divergent series  :

 

The convergent series   also satisfies this equation:

 

So from   we can neither conclude that the series converges nor that it diverges. We have to use a different convergence criterion in such a case.

Conducting the ratio test

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Decision tree for the ratio test

In order to apply the ratio test to a series  , we first form   and consider the limit:

  1. If  , then the series converges absolutely.
  2. If  , then the series diverges.
  3. If   for almost all  , then the series diverges.
  4. If we cannot apply any of the three cases, we cannot say anything about the convergence of the series.

Exercises

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Exercise 1

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Exercise

Investigate whether the series   converges or diverges.

How to get to the proof?

First we form the quotient   and consider its limit:

 

Thus  , with which it follows from the quotient criterion that the series converges absolutely.

Proof

The series   converges absolutely according to the ratio test, as

 

Exercise 2

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Exercise

Investigate whether the series   converges or diverges.

How to get to the proof?

There is  . Now, let us take a look at the quotient  

 

Now   and therefore also  . It follows that   for all   and thus in particular for almost all  . The ratio test now yields that the series diverges.

Proof

The series   diverges, because for   we have

 

Hint

You may already know that  . Accordingly, you can alternatively prove that  . However, this reasoning can mathematically only be applied after   has been proven within an analysis course.

Exercise 3

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Exercise

Investigate for which   the series   converges (absolutely) or diverges.

Proof

We use the ratio test with  :

 

Thus

 

Because the limit exists, limes superior and limes inferior coincide. Therefore

 

We are interested in for which   there is convergence, absolute convergence and divergence. From the ratio test it follows that the series converges absolutely if  . In the case   the ratio test yields that the series diverges. The case   must be examined separately:

Fall 1:  

We want to find out for which   the inequality   holds. By transformations we find:

 

For   or  , so if   holds, then the series converges absolutely.

Fall 2:  

Here, we have:

 

For   or   , i.e., for   the series diverges

Fall 3:  

And we have that

 

Since the ratio test does not provide a convergence statement here, we have to examine the two cases individually:

Fall 1:  

We have

 

Since this is a harmonic series, it diverges.

Fall 2:  

We have

 

The series is convergent according to the Leibniz criterion, but not absolutely convergent, since   diverges as it is a harmonic series.

Comparison: ratio and root test

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The ratio test is much easier to apply to some series than the root test. An example is the series  , whose convergence can be well proven with the ratio test:

 

For the root test, we must consider the following limit:

 

Here it is unclear whether there is convergence and against what. The fact that   grows rapidly could speak for a zero sequence. However, the sequence   is "weakened" by taking the  -th root. In fact,   can be shown (and thus   follows). However, this proof is very laborious. The situation is similar with the series  . By the ratio test,

 

Thus the sequence is divergent according to the ratio test.

For the root test we have to consider the following limit value:

 

One can prove that this sequence converges to  . However, this is laborious and requires additional convergence criteria that are often not available in a basic real analysis lecture. In both cases, the solution with the ratio test is easier.

However, there are also series that can be successfully investigated with the root criterion and for which the ratio test is not applicable. An example of this is the series

 

The ratio test is not applicable here: For the quotient sequence,

 

Thus  , since the quotient sequence for odd   is unbounded from above as  . On the other hand,   for all even   and thus for infinitely many quotients. Overall, however, we have to conclude that the ratio test is not applicable. On the other hand, the root test yields

 

Thus   and the series converges absolutely. So in the above example, the root test is applicable, while the ratio test gives no reasonable result.

In general, the root test has even a wider range of application than the ratio test: The root test can be applied to every series where the ratio test is successful. This is a consequence of the following inequality:

 

Here it becomes obvious: If  , then automatically  . If  , then automatically  . So if the ratio test is applicable, then the root test is applicable.

The converse is not true, as the above example shows. We will dispense here with the somewhat theoretical and lengthy proof of the inequality. Advanced students are welcome to try solving the corresponding Exercises.

Raabe's criterion

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In case the ratio test in the above form fails because, for example,  , there is a tightened form where one has to estimate the quotient sequence   more precisely. It is called Raabe's criterion and is an extension for ratio 1 of the ratio test. The name goes back to the Swiss mathematician Joseph Ludwig Raabe.

Raabe's criterion is often not as easy to apply as the ratio test and is often not covered in basic lectures. Therefore, we only mention it here and refrain from a derivation. For advanced students who want to derive the criterion, we recommend the corresponding Exercise. Raabe's criterion reads as follows

Theorem (Raabe's criterion)

  1. If   for almost all   with a constant  , then the series   converges absolutely.
  2. If   for almost all  , then the series   diverges.

Example (Raabe's criterion)

It is very easy to show the divergence of the harmonic series   using Raabe's criterion. Here,   so for all  , the following applies

 

So the series diverges.

Example (Raabe's criterion for convergence)

It is somewhat more difficult to prove the convergence of the series  . For any  :

 

With   we have that  . So the series converges absolutely.