1. Introduction
In this paper we will deal with Markov processes or dynamical systems in
. These processes or dynamics starting from
, denote by
,
, have associated evolution equations on
. In the Markov case we define for suitable
the function
which satisfied the Kolmogorov equation
where
L is the generator of the Markov process.
For a dynamical system we introduce
. Then this function is the solution of the Liouville equation
where now
L is the Liouville operator for the dynamical system, see e.g., Kondratiev and da Silva [
1].
Let
,
be a subordinator and
,
denotes the inverse subordinator, that is, for each
,
. This random process we consider as a random time and assume to be independent of
. Define a random process
by
Then as above we may introduce
For both Markov and dynamical system cases this function satisfies the evolution equations
where
L is the Kolmogorov or Liouville operator correspondingly. Here
is a generalized fractional time derivative corresponding to the inverse subordinator
, see
Section 2 below for details, in particular the definition in (
15). The main relation which is true for both cases is the following subordination formula:
where
is the density of the inverse subordinator
, see, e.g., Toaldo [
2], Kondratiev and da Silva [
1] and especially the book Meerschaert and Sikorskii [
3]. This formula which relates the solutions of the evolution equations with usual and fractional derivatives plays an important role in the study of dynamics with random times. Note that there exist such relations between random times, fractional equations and subordination in the framework of physical models, see, e.g., Mura et al. [
4].
The goal of this paper is to study and analyze the asymptotic behavior of two elementary dynamical system after the random time change, namely
,
and
,
. Here the dynamical system are considered as a deterministic Markov processes. For particular classes of random times the subordination formula (
1) is evaluated explicitly. This is true, for example, in the case of inverse stable subordinators. For a general inverse subordinator the properties of the density
are unknown and the evaluation of (
1) is not possible. Actually, it is a long standing open problem in the theory of stochastic processes.
We propose an alternative approach to study the asymptotic behavior of
. More precisely, we consider Cesaro limits (the asymptotic of the Cesaro mean of
, see (
23) below) of
using the subordination formula representation (
1) together with the Feller–Karamata Tauberian theorem, see Theorem 1. For many classes of random times this approach leads to a precise asymptotic behavior. In this paper we investigate three classes of random time change, denote by (
17)–(
19), see
Section 2, which exhibits different patterns of decays of the Cesaro limit of
. We would like to emphasize that for particular classes of random times, namely inverse stable subordinators, the asymptotic of
which may be computed explicitly, coincides with the Cesaro limit. For other classes of random times the Cesaro limit gives one possible characteristic of the asymptotic for
. To the best of our knowledge at the present time no other information on the asymptotic of
is known for a general subordinator.
The remaining of the paper is organized as follows. In
Section 2 we introduce three classes (
17)–(
19) of subordinator processes which serves as random times. These classes are given in terms of their local behavior of the Laplace exponent at
. In addition, we state the main results of the paper.
Section 3 is a preparation for the more general study of the asymptotic of the subordination in
Section 4. More precisely, we investigate in detail the special case of the inverse stable subordinator where explicit expressions are known. Hence, the expression for the subordination (
1) is derived (for the two dynamical systems considered above) as well as their Cesaro limit. It turns out that both asymptotic for
(the explicit calculations and Cesaro limit) are the same. Finally in
Section 4 we study the Cesaro limit for the general classes (
17)–(
19) of random time changes.
2. Random Times Processes
In this section we introduce three classes of subordinators which serves as random times processes. More precisely, the random times corresponds to the inverse of subordinator processes whose Laplace exponent satisfies certain conditions, see below for details. The simplest example in class (
17) below, is the well known
-stable subordinators whose inverse processes are well studied in the literature, see for example Bingham [
5] or Feller [
6].
The classes of processes to be introduced which serve as random times have a connection with the concept of general fractional derivatives (see Kochubei [
7] for details and applications to fractional differential equations) associated to an admissible kernels
which is characterized in terms of their Laplace transforms
as
, see assumption (H) below.
2.1. Definitions and Main Assumptions
Let
be a subordinator without drift starting at zero, that is, an increasing Lévy process starting at zero, see Bertoin [
8] for more details. The Laplace transform of
,
is expressed in terms of a Bernstein function
(also known as Laplace exponent) by
The function
admits the Lévy-Khintchine representation
where the measure
(called Lévy measure) has support in
and fulfills
In what follows we assume that the Lévy measure
satisfy
Using the Lévy measure
we define the kernel
k as follows
Its Laplace transform is denoted by
, that is, for any
one has
The relation between the function
and the Laplace exponent
is given by
We make the following assumption on the Laplace exponent of the subordinator S.
- (H)
is a complete Bernstein function (more precisely, the Lévy measure
has a completely monotone density
with respect to the Lebesgue measure, that is,
for all
,
) and the functions
,
satisfy
Example 1. A classical example of a subordinator S is the so-called α-stable process with index . Specifically, a subordinator is α-stable if its Laplace exponent isIn this case it follows that the Lévy measure is . The corresponding kernel has the form , and its Laplace transform is , . Example 2. Sum of two stable subordinators. Let be given and , the driftless subordinator with Laplace exponent given byIt is clear from Example 1 that the corresponding Lévy measure is the sum of two Lévy measures, that is,Then the associated kernel isand its Laplace transform is , . Let
E be the inverse process of the subordinator
S, that is,
For any
we denote by
,
the marginal density of
or, equivalently
The density is the main object in our considerations below. Therefore, in what follows, we collect the most important properties of needed in the next sections.
Remark 1. If S is the α-stable process, , then the inverse process , has Laplace transform (cf. Prop. 1(a) in Bingham [5] or Feller [6]) given bywhere is the Mittag-Leffler function. It follows from the asymptotic behavior of the function that as . It is possible to find explicitly the density in this case using the completely monotonic property of the Mittag-Leffler function . It is given in terms of the Wright function , namely , see Gorenflo et al. [9] for more details. For a general subordinator, the following lemma determines the
t-Laplace transform of
, with
k and
given in (
5) and (
6), respectively. For the proof see Kochubei [
7] or Proposition 3.2 in Toaldo [
2].
Lemma 1. The t-Laplace transform of the density is given byThe double ()-Laplace transform of is Here we would like to make the connection of the above abstract framework with general fractional derivatives. For any
the Caputo-Dzhrbashyan fractional derivative of order
of a function
u is defined by (see e.g., Kilbas et al. [
10] and references therein)
where
is given in Example 1, that is,
,
. In general, starting with a subordinator
S and the kernel
as given in (
5), we may define a differential-convolution operator by
The operator
is also known as general fractional derivative and its applications to convolution-type differential equations was investigated in Kochubei [
7].
Example 3. Distributed order derivative. Consider the kernel k defined byThen it is easy to see thatThe corresponding differential-convolution operator is called distributed order derivative, see Atanackovic et al. [11], Daftardar-Gejji and Bhalekar [12], Hanyga [13], Kochubei [14], Gorenflo and Umarov [15], Meerschaert and Scheffler [16] for more details and applications. We say that the functions
f and
g are
asymptotically equivalent at infinity, and denote
as
, meaning that
We say that a function
L is
slowly varying at infinity (see Feller [
6], Seneta [
17]) if
Below
C is constant whose value is unimportant and may change from line to line.
In the following we consider three classes of admissible kernels
, characterized in terms of their Laplace transforms
as
(i.e., as local conditions):
We would like to emphasize that these three classes of kernels leads to different type of differential-convolution operators. In particular, the Caputo-Djrbashian fractional derivative (
17) and distributed order derivatives (
18), (
19). Moreover, it is simple to check that the class of subordinators from Example 2 falls into the class (
17) above.
Remark 2. The asymptotic behavior of the function as may be determined, under certain conditions, by studying the behavior of its Laplace transform as , and vice versa. An important situation where such a correspondence holds is described by the Feller–Karamata Tauberian (FKT) theorem.
We state below a version of the FKT theorem which suffices for our purposes, see the monographs Bingham et al. [
18] (Section 1.7) and Feller [
6] (XIII, Section 1.5) for a more general version and proofs.
Theorem 1. Feller–Karamata Tauberian. Let be a monotone non-decreasing right-continuous function such thatIf L is a slowly varying function and , then the following are equivalentWhen , (20) is to be interpreted as ; similarly for (21). 2.2. Statement of the Main Results
In
Section 3 and
Section 4 we will focus our attention on deriving the asymptotic behavior of the subordination
given in (
1) for the inverse stable subordinator as well as for the classes (
17)–(
19) given above. On one hand, the results concerning the inverse stable subordinator as a random time are well understood, due to the fact that the Laplace transform (in
of the density
is known (cf. Remark 1). On the other hand, for a general subordinator much less information about
is known and explicit results for the subordination
are not available. In order to get around this problem, and motivated by the results of
Section 3, we study the Cesaro limit of
for the general classes of random times.
With the above considerations we are ready to state our main results.
Theorem 2. Let be the subordination by the density associated to the inverse stable subordinator. Denote by the Cesaro mean of .
- 1.
If , , then the asymptotic behavior of coincides with the Cesaro limit and is equal to - 2.
If , , then the asymptotic of and its Cesaro limit are equal to
The proof of Theorem 2 is essentially the contents of
Section 3 while the next theorem is shown in
Section 4.
Theorem 3. Let be the subordination by the density associated to the classes (17)–(19) and the Cesaro mean of . - 1.
Assume that , . Then the asymptotic of the Cesaro mean for the three classes are:
- (17).
as ,
- (18).
as ,
- (19).
as .
- 2.
If , , then the asymptotic of for the different classes are:
- (17).
as ,
- (18).
as ,
- (19).
as .
3. Inverse Stable Subordinators
In this section we consider two elementary solutions of dynamical systems, namely , and , , and investigate their subordination by the density of inverse stable subordinator.
Define the function
as the subordination of
(of the above type) by the kernel
, that is,
Our goal is to investigate the asymptotic behavior of
. At first we compute explicitly the function
by solving the integral (
22) and obtain the time asymptotic. Second we derive the Cesaro limit of
, more precisely, the asymptotic behavior of the Cesaro mean of
defined by
It turns out that both asymptotic behaviors for the two functions
given above coincide. Therefore, for the random time change associated to the inverse stable subordinator
,
, the asymptotic behavior of
is the same as the Cesaro limit. On the other hand, using the Cesaro limit we may investigate a broad class of subordinators. In
Section 4 we investigate the Cesaro limit for the classes (
17)–(
19) while in this section concentrate in the spacial case of inverse stable subordinators.
3.1. Subordination of Monomials
Let us consider at first the subordination of the function
,
. Hence,
is given by
It follows from (
11) that
is explicitly evaluated as
The last equality follows easily from the power series of the Mittag-Leffler function
In addition, the asymptotic of the Mittag-Leffler function
that gives
Now we turn to compute the asymptotic behavior of the Cesaro mean of
with the help of the FKT theorem. To this end we define the monotone function
The Laplace-Stieltjes transform
of
is given by
Using Fubini’s theorem and Equation (
12) we obtain
The r.h.s. integral can be evaluated as
which yields
On the other hand, for the stable subordinator we have
, cf. Example 1. Thus, we obtain
where
and
is a trivial slowly varying function. Then Theorem 1 yields
and this implies the following asymptotic behavior for the Cesaro mean of
Remark 3. In conclusion, we find that the asymptotic behavior of the subordination of any monomial by the density (of the inverse stable subordinator) as well as its Cesaro limit coincides. Note also the slower decay of the subordination compared to due to .
3.2. Subordination of Decaying Exponentials
Now we consider the solution , and proceed to study the asymptotic behavior of its subordination by the kernel . Again a direct computation is possible in that case as well as the Cesaro mean.
Hence, the subordination
is given by
It follows from Equation (
11) that
On the other hand, to derive the asymptotic behavior for the Cesaro mean of
(with the help of Theorem 1) we define the monotone function
The Laplace-Stieltjes transform
of
is equal to
and using Fubini’s theorem and Equation (
11) we obtain
As
for the class (
17) we may write
as
It is simple to verify that
L is a slowly varying function so that we may use the FKT theorem to obtain
Dividing both sides by
t leads to the asymptotic behavior of the Cesaro mean of
, that is,
Remark 4. We conclude that the asymptotic behavior given in (30) coincides with the Cesaro limit of . In addition, we notice that the starting function has an exponential decay and its subordination has a slower decay, namely polynomial decay.