Serlo: EN: Application of convergence criteria

Many problems in real analysis lectures (and also in applications afterwards) involve the investigation whether a certain series converges or diverges. This page offers you a collection of methods how to tackle such problems. We present strategies that experienced mathematicians use to successfully prove or disprove convergence. These strategies are then applied to some practical examples

Methods for investigating convergence

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Using the term test

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A series   can never converge, if the corresponding sequence   does not converge to 0. It therefore makes sense to first try to find the limit of  . If this limit doesn't exist or is not 0, you instantly know that   diverges

If you find out that   converges to 0, the next question is: How fast does it converge to 0? If it goes to 0 slower than   (harmonic series) you can expect divergence. The harmonic series is the "fastest decaying series that still diverges". By contrast, if   decays faster than   for some   (geometric series) you know that it converges. The geometric series is "one of the slowest decaying series that still converges". It is a useful idea, to compare   to a harmonic or geometric series in order to disprove or prove its convergence.

Ratio test

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This test is virtually a comparison to a geometric series. It is often useful for series in quotient form   . If  , then the series converges absolutely by the ratio test, since it is bounded by some geometric series   (with some constant  ). In that case, any   serves for such a bound. However, for  , the series diverges. In case  , we cannot say anything about the convergence and have to use a different test.

Root test

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This test is also effectively a comparison to a geometric series. It is particularly useful for power series like   or  . Absolute convergence holds for   or   . However, for   or   we have divergence. If the sequence   or   converges, we can replace the   with a  . If the   equals  , we again cannot make any conclusions and need a different test.

Alternating series test

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Alternating series call for being treated by the alternating series criterion. According to it, any series   or   converges if   is a monotonously decreasing null sequence. "Monotonously decreasing" makes sure that   (if   are the positive elements). By "null sequence", we know that all   sum up to   at most and that the   are positive. There are alternating series, for which   does not meet these two criteria. Then, the alternating series test does not work - even though we have an alternating series. If   is not a null sequence, the series even diverges by the term test. If   is a null sequence that does not decrease monotonously, we need to search for a different criterion.


Direct comparison

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Direct comparison is useful, if we have a fraction of polynomials - like  . The ratio test and the root test may fail in this case. In particular,   and   might be complicated and therefore difficult to handle. It is easier to compare the fraction to a convergent series   (i.e. power 2 in the denominator) or to a divergent harmonic series   (power 1). In general, convergence can be established by comparison to   with any power   and divergence by comparison to   with a power   . The convergence proof requires bounding   from above and   from below. The divergence proof works vice versa. If the polynomials   have some degrees  , the following rule of thumb holds: If  , the series converges . If   ,it diverges. For a mathematical proof, we can then use a direct comparison to a series   with some constants  .

Decision tree for convergence and divergence

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The tricks above can be visually represented in a decision tree:

 
Decision tree for convergence and divergence

Applications

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Example 1

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We consider the series

 

The coefficient sequence is

 

This is a null sequence. We already proved   for natural numbers  . The squeeze theorem implies   for all rational  . The sequence is not alternating, since its elements are positive. As it is a sequence of quotients, we might have good luck with the ratio test:

 

In the limit  , there is

 

So the ratio test applies and our series   converges absolutely. Done with it!

Example 2

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Next, we consider the sequence

 

Again, we have a null sequence of elements:

 

This will get obvious when we write   . There is   , so also  . This sequence is again not alternating as all elements are positive. We have a quotient, which suggests taking the ratio test. But there is also a power of  , which suggests using the root test. Handling powers of   by the ratio test is tedious, so we try the root test first, i.e. we take the  -th root:

 

Since

 

the root test succeeds and our series   converges absolutely.

Example 3

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Now, we investigate the alternating series

 

The corresponding sequence

 

is a null sequence, since  . At this point, the alternating series test seems the first option. In order to apply it, we need to check whether   is monotonously decreasing. For all  , there is:

 

So   is monotonously decreasing. By the alternating series test, we know that the series   converges. But does it also converge absolutely? We need to investigate whether the series   converges. This scales like a harmonic series, so it should not converge. And indeed, we can compare it to a harmonic series:

 

As the harmonic series   diverges, we also have divergence of the scaled version   and by direct comparison, the series   diverges. So our series   is convergent, but not absolutely convergent.

Example 4

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We consider the following quotient of polynomials:

 

The coefficient sequence is   with

 

The two polynomials in the fraction   are   and  . Its degrees are

 

which implies absolute convergence by direct comparison: The coefficient sequence scales like   for large  . We can therefore bound it from above by   with   . Explicitly, we can do this by increasing the enumerator and decreasing the denominator:

 

The series   converges, so also our series   converges absolutely (and   is an upper bound for it).

Example 5

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Our last example is another alternating series:

 

It may be tempting to use the alternating series test, here. However, we should first check whether the sequence of elements is even a null sequence:

 

Apparently,   is not a null sequence! So we can not apply the alternating series test. However, we instantly know that   is neither a null sequence and can directly apply the term test. By means of the term test, our series   diverges.