Here we are going to
present some conditions that enables us to interchange the order of
integration which is often not covered by classic Fubini's Theorem or
its variants. We assume readers are familiar with basic theory of
LebesgueStieltjes integration. (Refer to this article for the definition of terms that are used throughout this post)
1. Preliminaries
We start with two definitions that slightly extends the concept of improper Riemann integral and antiderivative, respectively.
Let be a locally integrable function defined on the set of positive real numbers, be a complexvalued function on , and be a complex number. Suppose it happens that is of bounded variation on and converges to whenever is an increasing sequence of closed bounded intervals with . Then we say is improperly integrable with respect to on , or simply, is improperly integrable on . Also, we call the (improper) integral of on and denote this fact by
1. Preliminaries
We start with two definitions that slightly extends the concept of improper Riemann integral and antiderivative, respectively.
Let be a locally integrable function defined on the set of positive real numbers, be a complexvalued function on , and be a complex number. Suppose it happens that is of bounded variation on and converges to whenever is an increasing sequence of closed bounded intervals with . Then we say is improperly integrable with respect to on , or simply, is improperly integrable on . Also, we call the (improper) integral of on and denote this fact by
If is the identity function, then the LebesgueStieltjes integral reduces to the usual Lebesgue integral, and we may drop . Then it is clear that every integrable function on is also improperly integrable with same integral value.
We make another convention that, if and (or , resp.) is improperly integrable with respect to on , we often denote its integral as (or , resp.).
Next, we extend the concept of antiderivative. A function is called an measure if

(a) it is rightcontinuous on its domain,

(b) it is of boundvariation on any closed interval with , and

(c) and converges to a finite limit.
We denote as , if no confusion arises.
Several important classes of functions fall into the category of measures. Some examples are immediate:
1.1. Example. Let be an improperly integrable function on . Then the function , defined as for and , is an measure. Its verification is straightforward.
1.2. Example. Let be a sequence of complex numbers such that converges (either absolutely or conditionally). Then defined for is an measure.
Now we define the LaplaceStieltjes transform of an measure as
For this definition to make sense, we must check that is improperly integrable for an appropriate domain of . We claim that this is the case when or . The former is immediate by (a) and (c) of the definition of measure, so assume . Let be a function which coincides with on the set of continuity of and is regularized at each discontinuity of . Simply, this means that is defined as
Then for , integration by parts for LebesgueStieltjes integral yields
where the last integral is a Lebesgue integral. Since is integrable on , taking and applying Dominated Convergence Theorem completes the proof of our claim. We also obtain an identity which deserves its own right:
We make additional note that, if is as in Example 1.1, then and the LaplaceStieltjes transform reduces to the ordinary Laplace transform.
2. Main Theorem
Now we state our main theorem:
2.1. Theorem. Let be an measure, and be its Laplace transform. Then
Assuming this theorem, we obtain
2.2. Corollary. Let and be as in Theorem 2.1. Then for
and for ,
This corollary can be regarded as changing the order of integration, since the equality clearly holds if is replaced by . As an instance, this provides a very simple way to calculate the famous Dirichlet integral
We choose , as in Example 1.1. Then , hence Corollary 2.2.(a) with yields
Several important classes of functions fall into the category of measures. Some examples are immediate:
1.1. Example. Let be an improperly integrable function on . Then the function , defined as for and , is an measure. Its verification is straightforward.
1.2. Example. Let be a sequence of complex numbers such that converges (either absolutely or conditionally). Then defined for is an measure.
Now we define the LaplaceStieltjes transform of an measure as
For this definition to make sense, we must check that is improperly integrable for an appropriate domain of . We claim that this is the case when or . The former is immediate by (a) and (c) of the definition of measure, so assume . Let be a function which coincides with on the set of continuity of and is regularized at each discontinuity of . Simply, this means that is defined as
Then for , integration by parts for LebesgueStieltjes integral yields
where the last integral is a Lebesgue integral. Since is integrable on , taking and applying Dominated Convergence Theorem completes the proof of our claim. We also obtain an identity which deserves its own right:
We make additional note that, if is as in Example 1.1, then and the LaplaceStieltjes transform reduces to the ordinary Laplace transform.
2. Main Theorem
Now we state our main theorem:
2.1. Theorem. Let be an measure, and be its Laplace transform. Then

(a) is analytic for with

for ,

(b) as in Stolz angle,

(c) as in Stolz angle,

(d) , either as or as , in Stolz angle for .
Assuming this theorem, we obtain
2.2. Corollary. Let and be as in Theorem 2.1. Then for
and for ,
This corollary can be regarded as changing the order of integration, since the equality clearly holds if is replaced by . As an instance, this provides a very simple way to calculate the famous Dirichlet integral
We choose , as in Example 1.1. Then , hence Corollary 2.2.(a) with yields
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