1. Introduction
The concept of almost periodicity was first proposed by the Danish mathematician, H. Bohr [
1,
2,
3]. Once this concept was put forward, it immediately attracted the attention of many famous mathematicians, such as W. Stepanov, H. Weyl, N. Wiener, S. Bochner, and so on. They put forward many important generalizations and variants of Bohr almost periodic concept. It is worth mentioning that the generalization of the concept of almost periodic functions can be considered in two different ways. One is to use Bohr property or Bochner property to define almost periodic functions in more general function spaces, and the other is to define almost periodic functions as the elements in the closure of the set composed of trigonometric polynomials in a more general function space according to a certain norm or seminorm. A. S. Besicovitch adopted the second approach [
4,
5,
6,
7,
8,
9,
10,
11,
12].
On the one hand, Besicovitch’s almost periodicity is a natural extension of Bohr’s almost periodicity [
4,
5,
7]. The space of Besicovitch almost periodic functions is the completion of trigonometric polynomials in the form of
with respect to the seminorm
where
(see in [
5,
7]). The Besicovitch almost periodic functions defined in this way (denote by
the space of all such functions) possess both the Bohr and the Bochner properties [
7]. C. Corduneanu and A.S. Besicovitch have given some basic properties of Besicovitch almost periodic functions in [
5,
7]. Besicovitch almost periodic functions can also be defined in Marcinkiewicz space using the Bohr property or the Bochner property. However, Besicovitch almost periodic functions defined in the above ways are equivalent classes of functions rather than usual functions. This brings great difficulties to the study of Besicovitch almost periodic solutions of differential equations. Therefore, there are few results on Besicovitch almost periodic solutions of differential equations.
On the other hand, it is well known that the existence of periodic solutions and almost periodic solutions is one of the important research contents of the qualitative theory of differential equations, see in [
13,
14,
15,
16,
17,
18,
19,
20,
21,
22] and the references therein. Nevertheless, there are still few results on the existence of Besicovitch almost periodic solutions for differential equations [
23].
Based on the above discussion, the main purpose of this paper is to study some basic properties of Besicovitch almost periodic functions defined in the first way, that is, to give the definition of Besicovitch almost periodic functions by using the Bohr property and the Bochner property, respectively, and to study some basic properties of this kind of Besicovitch almost periodic functions, including composition theorem and proves the equivalence of Bohr’s definition and Bochner’s definition. As an application, the existence and uniqueness of Besicovitch almost periodic solutions for a class of abstract semi-linear delay differential equations are studied by using the contraction fixed point theorem.
The remainder of this paper is arranged as follows. In
Section 2, we introduce some basic definitions and lemmas. In
Section 3, we first give the definition of Besicovitch almost periodic functions by using the Bohr property, deduce some basic properties of Besicovitch almost periodic functions in Bohr’s sense, including translation invariance and composition theorem, and then prove the equivalence between the concept of Besicovitch almost periodic functions defined by the Bohr property and the concept of Besicovitch almost periodic functions defined by the Bochner property. In
Section 4, we study the existence and uniqueness of Besicovitch almost periodic solutions for a class of abstract semi-linear delay differential equations. In
Section 5, we give a brief conclusion.
3. Besicovitch Almost Periodic Functions
Lemma 4 ([
7])
. The set is a closed linear manifold in . Define a relation in
as follows:
One can easily verify that the relation ≃ is indeed an equivalence relation.
The quotient space is the set of equivalence classes with respect to the relation ≃, organized in accordance with the operations , , and for and for .
Definition 2 ([
7])
. The quotient space is called Marcinkiewicz space and denoted by . Lemma 5 ([
7])
. The Marcinkiewicz function space is a Banach space with the norm defined bywhere Remark 1. One can easily check that for every .
Remark 2. If , then .
Definition 3 (Bohr’s definition). Let , then f is said to be Besicovitch almost periodic if f posses the following two properties:
- (1)
f is uniformly continuous in the -norm, and
- (2)
for every , there is an such that each interval with length l contains a number satisfying
The τ is called a ε-translation number of f. The set of such functions will be denoted by . For , we denote .
Remark 3. R. Doss has used the Bohr property to define Besicovitch almost periodic functions in space [4,24,25]. Here, we use the Bohr property to define Besicovitch almost periodic functions in Marcinkiewicz space space . Therefore, Doss’s Besicovitch almost periodic functions are ordinary functions, while the Besicovitch almost periodic functions defined by Definition 3 are not ordinary functions but the equivalence classes of functions. In the sequel, let us denote by the set of all functions that satisfy the condition (1) in Definition 3.
Remark 4. It should be noted that, in general, when we write that a function we do not have in mind the function f itself, it does represent a whole class that is equivalent to f.
Lemma 6. Let and , then .
Proof. As
, for every
, there is an
such that each interval with length
l contains a number
satisfying
Noting that
One concludes that
. This completes the proof. □
Remark 5. In the proof of Lemma 6, the f’s in the left side of the formula are equivalence classes and the f’s in the right side are representative elements of the equivalence classes. We will not make an explanation later, it is clear from the context.
Lemma 7. If and , then .
Proof. For every
, there exists an
such that each interval of length
l contains a
satisfying
Noting the fact that
We have
. The proof is completed. □
Lemma 8. If , then we have that the family is relatively compact in the topology of .
Proof. If
, then
is a sequence of translates of
f. By
, there exists an
such that every interval
contains a number
in this interval with the property that
From Definition 3, one has that
f is uniformly continuous in the norm
, that is, there is a
such that
for all
with
. Moreover, for every
, one has
, which implies that there exists a subsequence
such that
is convergent. Consequently, there is an integer
such that
for
. It follows from (
2) and (
3) that
which implies that
is uniformly convergent in the
-norm, thus, the family
is relatively compact. This completes the proof. □
Definition 4 (Bochner’s definition). Function is called Besicovitch almost periodic if for every sequence , there exists a subsequence such that converges in the norm .
Lemma 9. The Bohr definition and the Bochner definition of Besicovitch almost periodicity are equivalent.
Proof. According to Lemma 8, one can easily see that Bohr’s definition implies the Bochner definition. To finish the proof, we only need to prove that the Bochner definition implies the Bohr definition, that is, for
, we need to show that if the set
is relatively compact set of
, then
f posses Bohr’s property, that is, for each
, there exists an
such that in every interval
, there exists a
such that
Otherwise, if
f does not possess Bohr’s property, then one can find a
such that
does not exist. That is to say, for every
, we can find an interval of length
l that does not contain any
such that (
4) holds. Now, choose an arbitrary
and an interval
of length larger than
such that
does not contain any
satisfying (
4). Set
, then
, and thus
cannot be chosen as
, which implies that
Let us choose an interval
of length larger than
that does not contain any
such that (
4) holds. Continue this process, letting
, then one has
,
, and this implies that
and
cannot be chosen as
, that is,
and
Proceeding similarly, one constructs the numbers
with the property that none of the differences
,
, could be chosen as number
in (
4). Therefore, for
, one gets
Therefore, one obtains
which contradicts the property of relative compactness of the family
. Consequently,
f does posses Bohr’s property. The proof is completed. □
Lemma 10. Let satisfy that there exists with as , then .
Proof. It is easy to see that
f is uniformly continuous in the norm
. As
as
, for any
, there is a large enough integer
such that
Because
, then there is an
such that every interval of length
l contains a number
satisfying
Consequently, we have
which implies that
. The proof is completed. □
Using the proof method of Proposition 3.21 in [
7], one can easily show that
Lemma 11. If , then for each , there are common ε-translation numbers for these functions.
Lemma 12. Let , then .
Proof. According to Lemma 11, for any
, there exists
such that every interval of length
l contains a
with the property
Hence, we have
therefore,
. The proof is complete. □
Lemma 13. The space is a Banach space with the norm .
Proof. Clearly, and by Lemma 10, the space is closed. Therefore, is also a Banach space. The proof is complete. □
Remark 6. Unlike in the case of Bohr almost periodic functions, the product does not necessarily belong to . However, we replace a Besicovitch almost periodic function with a Bohr almost periodic function, the result is still valid.
Lemma 14. If and , then we have .
Proof. Clearly, we have and is uniformly continuous in the norm . As , for any sequence of real numbers there exists a subsequence of such that converges uniformly on . As it follows that for the sequence , there exists a subsequence such that the sequence of functions converges in the norm . It is then clear that converges uniformly in .
Now, for any
, there exists a large enough integer
such that
for
, which means that
converges in the norm
. Hence,
satisfies the Bochner definition, namely,
. The proof is complete. □
Lemma 15. If and , then .
Proof. Step 1. We will show that
. Since
and
,
f and
x are bounded and uniformly continuous in their corresponding norms, and for every
, there exists
such that
for
. By the fact that the set
and the boundedness of
f and
x, one can easily get that
is bounded in
. Thus,
. From (
5), we have
Therefore,
is uniformly continuous.
Step 2. We will show that . Thanks to Lemma 9, to complete the proof, we only need to show the family is relatively compact.
As
,
, by Lemmas 2 and 9, for any
and
, we can have
where
and
is mentioned in Step 1. By the uniform continuity of
f in the norm
, denote
, one gets
for
, which means that the function
satisfies the Bochner definition. Therefore,
. The proof is complete. □
Let be a Banach space.
Definition 5. A function with for each , is said to be Besicovitch almost periodic in uniformly in if the following properties hold true:
- (1)
For every bounded subset , is uniformly continuous in with respect to the norm uniformly for .
- (2)
For each and each bounded subset , there exists such that every interval of length l contains a number τ with the property uniformly in .
The collection of these functions will be denoted by .
4. Besicovitch Almost Periodic Solutions
Consider the following semi-linear differential equation with delay:
in which
A is the infinitesimal generator of a
-semigroup
on a Banach space
,
is a measurable function.
A function
is said to be a mild solution of (
6), if for
, where
and
, it satisfies the integral equation
In the following, in order to distinguish, let
and
be the set of functions
with
uniformly in
, where
is any bounded subset of
. The quotient spaces corresponding to
and
are denoted by
and
, respectively.
We assume that the following conditions hold throughout the rest of the paper:
and F satisfies .
There exist positive constants
and
such that for all
and
,
and
.
A is the infinitesimal generator of an exponentially stable -semigroup , that is, there exist numbers such that .
, where N is defined in .
Let
with the norm
.
Lemma 16. The space is a Banach space when it is endowed with the norm .
Proof. Let
be a Cauchy sequence in
. Then, for every
, there exists a positive integer
such that
Because
is a Banach space and
, so there exists
such that
as
. As
, we have
which implies that
by the completeness of
. Moreover, we have
. In view of (
7), for every
, there is a large enough
such that
. Due to the fact that
is uniformly continuous with respect to the norm
, there is a
such that
for
. Therefore, we have
which means that
is uniformly continuous in the norm
. Denote by
the
-translation number of
, then
which yields
. Therefore,
. The proof is completed. □
Lemma 17. Let and hold. If , then and .
Proof. Step 1, we will prove that
. As
, so
, then
which means
. In addition, in view of Lemma 15, we see that
. Thus,
.
Step 2, we will show that
. Based on
, for all
, one has
which implies
. Moreover, by virtue of the Minkowski inequality, one get
then
which implies
.
Step 3, we will prove that
. As
, there exists a bounded subset
such that
for all
. From Lemma 11 it follows that for each
, there exists an
such that every interval of length
ℓ contains an
h satisfying
and
Based on the inequalities above, for
and
, one gets
which means that
. This completes the proof. □
Lemma 18. Let – hold. If , then the function defined bybelongs to . Proof. By Lemma 17, one sees that
. First of all, let us to show that
U is well defined. According to
, one has
which implies that
Therefore,
U is well defined, in addition, one has gained that
.
Next, we will prove
. As
, from Lemma 17, we have
. Based on this fact, for every
, let
be the
-translation number of
, then we have
In addition, by using the Höld inequality, we have
where
.
By a change of variables, Fubini’s theorem and Lebesgue’s dominated convergence theorem, from the inequality above, we have
thus
which implies that
meets Bohr’s property. When
is replaced by a small enough real number, we see that
is uniformly continuous. Consequently,
. The proof is completes. □
Definition 6. By a Besicovitch almost periodic mild solution of system (
6),
we mean that and x satisfies Theorem 1. If – hold, then system (
6)
posses a unique Besicovitch almost periodic mild solution. Proof. Consider the operator
defined by
By Lemma 18, we see that
is well defined and maps
into
. Therefore, we only need to prove that
is a contraction mapping. Indeed, for every
, one has
which combined with
yields
Thus,
is a contraction mapping from
to
. By the Banach fixed point theorem,
posses a unique fixed point in
. Consequently, system (
6) posses a unique Besicovitch almost periodic mild solution. The proof is completed. □
Finally, we present an example to illustrate the feasibility of our results obtained in this section.
Example 1. where andTake for and is absolutely continuous on . It is well known that A generates a semigroup with the property that for . Clearly, , , . By a simple calculation, we have . Therefore, conditions – are verified. Therefore, by Theorem 1, system (
9)
posses a unique Besicovitch almost periodic solution.