Cauchy condensation test – Serlo

In this chapter, we present the Cauchy condensation test (named by Augustin Louis Cauchy). It allows us to only check the condensed series for convergence , which contains way less elements than the original series . More precisely, in case the series elements are non-negative and decreasing, we know that the original series converges if and only if the condensed series converges. The derivation will involve a direct comparison to a divergent harmonic series and convergence to a convergent generalized harmonic series für .

Repetition and derivation of the criterion

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For proving divergence of the harmonic series   , we used a lower bound for each  -th partial sum   :

 

How can we generalize this concept to a general series   ? In order to make the same estimation steps, the series must have some properties identical to the harmonic series:

  • The series elements   have to be non-negative.
  • The sequence of elements   has to be monotonously decreasing.

If   is a series with non-negative elements fulfilling   for all  . Then

 

So we estimated   from below by   . That means, that if the condensed series   diverges and hence,   as well, then the series   also diverges by direct comparison. Conversely (by contraposition), if   converges, then   converges, as well.

For the proof that the generalized harmonic series   with   converges, we compared the  -th partial sum   for   to a convergent geometric series   . The bounding worked as follows:

 

We try to do the same for a general series   with

  • non-negative elements  
  • and   for all   (monotonously decreasing sequence of elements)

Let  . then,

 

So we can also bound   from above by   . Direct comparison can again be applied and leads us to the conclusion: If the condensed series   converges, the the original series   also converges.

So if elements are non-negative and monotonously decreasing, we have an equivalence between the convergence of the series   and the condensed series   . This result is called Cauchy condensation test. It can be very useful, to remove logarithms out of a series. For instance, if  . Then, for the condensed series  . So condensation can remove double logarithms.

Now, let us formulate these findings in a mathematical language, i.e. a theorem with a proof:

Theorem (Cauchy condensation criterion)

Let   be a non-negative and monotonously decreasing sequence. Then, the series   converges if and only if the condensed series   converges.

Proof (Cauchy condensation criterion)

Proof step: " "

For the sequence of partial sums   there is

 

If the sequence / series   converges, then also the subsequence   will converge. The above bounding implies that then also   converges. Multiplying by  , we also get convergence of the condensed series  .

Proof step: " "

For the  -th partial sum   and for  , there is:

 

now, if the series   converges, then by the above estimate,   must be bounded and hence convergent.

Hint

Analogously, one can show that a non-positive series with elements monotonously increasing (e.g. up to 0) converges, if and only if the condensed series converges.

Warning

The condensation test is NOT treated in all calculus courses. The main reason for this is that there are not too many applications, where it is useful. Basically only for eliminating logarithms. Please, only quote this test in your exercise solution, if it was treated somewhere in the lecture! Otherwise, you may reduce the condensation test to a direct comparison test, by making the same estimates as in the proof above.

Applications

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Application of the condensation test (Video in German:YouTube-Video vom YouTube-Channel Quatematik)

Example (Cauchy condensation test and the zeta function)

As seen above, the Cauchy condensation test can be used to prove the convergence / divergence for the generalized harmonic series   for  . This series converges if and only if the condensed series converges:

 

This is just a geometric series   with  . It converges if and only if

 

By the Cauchy condensation test, the generalized harmonic series   converges if and only if   . Especially, for   , it diverges. Usually, in the convergent case  , one defines the

Riemann zeta function as the limit of this generalized harmonic series  .

You may just use in an exercise that this result is finite, without referring to the Cauchy condensation - or any other test especially,  

Exercise (Removing logarithms)

Investigate for   whether the series   converges.

Proof (Removing logarithms)

By means of the Cauchy condensation test, this series converges if and only if the following condensed series converges:

 

This is just a generalized harmonic series with a constant pre-factor  . The example above shows that this series converges if and only if   and diverges if and only if   .