Absolute Convergence of Improper IntegralsAbsolute Convergence of Improper Integrals
Since most of the tests of convergence for improper integrals are only valid for positive functions, it is legitimate to wonder what happens to improper integrals involving non positive functions. First notice that there is a very natural way of generating a positive number from a given number: just take the absolute value of the number. So consider a function f(x) (not necessarily positive) defined on [a,b]. Then let us consider the positive function |f(x)| still defined on [a,b]. It is easy to see that both functions f(x) and |f(x)| will exhibit the same kind of improper behavior. Therefore, one may ask naturally what conclusion do we have if we know something about the integral
We have the following partial answer:
is convergent, then the integral 
is also convergent.
We have to be careful the converse is not true. Indeed, the improper integral
is convergent while the improper integral
is divergent. This is quite hard to show. On the other hand, it shows that the convergence of 
carries more information than just convergence. In this case, we say that the improper integral 
is absolutely convergent. And if the improper integral is convergent while the improper integral is divergent, we say it is conditionally convergent.
Example. Establish the convergence or divergence of
Answer. We have an improper integral of Type II. Since the function 
is not positive on 
, we will investigate whether the given improper integral is absolutely convergent. Hence we must consider the improper integral
Let us check whether we have a Type I behavior. Clearly the point 0 is a bad point. We leave it as an exercise to check that the function 
is indeed unbounded around 0. So we must split the integral and write
First let us take care of the integral
We know that 
when 
. Hence we have
when 
. Since the integral 
is convergent via the p-test, the limit test enables us to conclude that the integral
is convergent. Next we take care of the improper integral
We can not use the limit test since the function 
does not have a nice behavior around 
. But we know that
for any number x. Hence we have
for any 
. Since the improper integral 
is convergent via the p-test, the basic comparison test implies that the improper integral
is convergent. Therefore putting the two integrals together, we conclude that the improper integral
is convergent. This clearly implies that the improper integral
is absolutely convergent.
Example. Show that the improper integral
is convergent.
Answer. As we mentioned before, this improper integral is not absolutely convergent. So there is no need of considering the absolute value of the function. Note that the integral is improper obviously because of . 0 is not a bad point since
But even if it is not a bad point, we will isolate it by writing
The integral 
is not improper. So we concentrate on the integral
We know by definition that
Now consider the proper integral 
. An integration by parts gives
Since
and
we get
Note now that the improper integral 
is in fact absolutely convergent. Indeed, we have
and since by the p-test the improper integral 
is convergent, the basic comparison test implies the desired conclusion, that is 
is convergent. Therefore the improper integral is convergent. Since
then the improper integral 
is convergent.
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Mohamed A. Khamsi