The Particular Case of Positive SeriesThe Particular Case of Positive Series
Consider the series 
and its associated
sequence of partial sums 
. Here we will assume that the
numbers we are about to add are positive, that is, 
for any
. It is clear that the process of generating the partial
sums will lead to an increasing sequence, that is,
,
for any . Our previous knowledge about increasing sequences
implies the following fundamental result:
for any
is
convergent, if and only if, the sequence of partial sums is
bounded; that is, there exists a number M > 0 such that
, .
This result has many implications. For example, we have the following
result (called The Basic Comparison Test):
.
such that
,
then the series is convergent.
such that
,
then the series is divergent.
Recall that in previous pages, we showed the following
,
which means that the series 
is divergent.
Example: Show that the series
is divergent.
Answer: We have 
, for any ; hence
.
Since is divergent, we
deduce from the Basic Comparison Test, that 
is divergent.
Example: Show that the series
is convergent.
Answer: Since
and the geometric series 
is convergent, then the series 
is convergent (using the Basic Comparison
Test).
The next result (known as The p-Test) is as fundamental as the
previous ones. Usually we combine it with the previous ones or new
ones to get the desired conclusion.
Consider the positive series (called the
p-series) 
. Since the
limit of the numbers must add to 0, in order to expect convergence, we
assume that p > 0. The next result deals with convergence or
divergence of the series
when p >0.
converges, if and only if, 
.
The proof of the above result is very instructive by itself. So let
us discuss how this works:
defined by
.
It is easy to check that f(x) is decreasing on 
. Hence,
for any , we have for any 
,
which implies
,
that is,
.
Using this inequality, we get
and
.
If 
, then we have
and if p=1, then we have
.
.
Since 
, then the series is not bounded,and therefore it is divergent.
but, since
,
we get
,
which means that the sequence of partial sums associated to the series
is bounded. Therefore,
the series is convergent.
is divergent. Though one
may want to easily check that we have
,
which shows that the sequence of partial sums is not bounded.
Example: Discuss the convergence or divergence of
.
Answer: It is not hard to show that for any , we have
. Then, we have
.
Since, by the p-Test, the series 
is
convergent, the Basic comparison Test implies that 
is convergent.
The last result on positive series may be the most useful of all.
Indeed, the Limit Test should be always in mind when it comes to
cleaning up some undesirable terms.
Before we state this test, we need a new notation. Indeed, we will
say that the two sequences 
and 
are equivalent, or 
, if and only if,
.
Then
and 
be two positive series such that
. converges, if and only if, converges.
Example: Determine whether the series
is convergent or not.
Answer: Note that when n is large we have 
and 
. Then it is easy to check that
.
Using the p-test we get that the series 
is convergent. Hence, by the Limit-test, we deduce
the convergence of the series 
.
Example: Determine whether the series
is convergent or not.
Answer: We know that
.
This limit means that when x is very small 
, then
(a very useful conclusion in physics, for example,
when dealing the motion of the pendulum). So when n is large, 1/n
will be small and therefore 
. This clearly
implies that
Since the series is
divergent, the limit-test implies that the series
is
divergent.
Remark: It should be appreciated that, without the Limit-test, it would be very hard to check the convergence.
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Mohamed A. Khamsi