1. Introduction
In the works of Lebedeva [
1], regarding the number of periodic solutions of equations first order, they required a high degree of smoothness. Franco et al. required the smoothness of the second derivative of the Schwartz equation [
2]. We have all of these restrictions lifted. Our new form presented also emphasizes this novelty.
There are two classes of oscillatory processes, periodic and non-periodic. In theory and practice, an intermediate class of almost periodic oscillations is of great importance.
Almost periodic oscillations are oscillations that are close to periodic oscillations, which are composed of harmonics with incommensurable periods. The process, which consists of the sum of two periodic oscillations with incommensurate frequencies, is also an almost periodic oscillation.
The theory of almost periodic oscillations began to develop in the works of the Latvian mathematician P.G. Bol, the Danish mathematician H.A. Bohr, and others.
Bol [
3] laid the foundations of almost periodic functions theory and quasiperiodic functions theory, proved the theorem on the decomposability of quasiperiodic functions in a Fourier series and the theorem on a quasiperiodic function.
Harald Bohr’s scientific papers relate mainly to functions theory. He made a great contribution to development of the almost periodic functions theory [
4]. Uniform almost periodic functions are named after Harald Bohr.
Fundamental results in the theory of periodic and almost periodic oscillations obtained in the works of V.A. Pliss [
5].
In many problems of classical mechanics, celestial mechanics, robotics, and mechatronics, there are processes in which the time dependence is not periodic, but they can be expressed through trigonometric sums. In this connection, interest has arisen in the study of almost periodic solutions of differential equations and differential equations with almost periodic coefficients [
6,
7,
8,
9,
10,
11,
12,
13,
14].
Over the last years, the question of studying almost periodic functions in robotics [
15,
16,
17,
18,
19,
20,
21], dynamic systems [
22,
23,
24,
25,
26], stability theory [
27,
28,
29,
30,
31], control systems for space objects [
32,
33,
34], and economy problems [
35,
36,
37,
38] arose significantly.
2. Upper Bound for Number of Almost Periodic Solutions
Let the right-hand side of equation be
Theorem 1. If the right-hand side of Equation (1) for each fixedis an increasing function with respect to, and there exists an instant, such thatis strictly increasing, then Equation (1) can have at most one almost periodic solution.
Proof. Suppose that the conditions of the theorem are satisfied, and conversely that Equation (1) has two almost periodic solutions,
and
, starting at
at
and
, respectively. It can be proven that solutions
and
do not intersect [
35], and therefore, without loss of generality, the following equation can be assumed to hold for all
:
Then, by the monotonicity of the function
, for all
the following inequality is true:
and for
, due to strict increase of the function
and due to Inequality (2),
Without a loss of generality, it can be assumed that .
Let an arbitrary
be taken. Then,
Indeed, by (3) , and from the continuity of the function it follows that Inequality (4) holds in some neighborhood of point ; consequently the given statement is true.
Let an arbitrary
be taken. By assumption, the functions
and
are almost periodic, and consequently they have a common
-almost period. Hence, there exists
, such that
and
Then, on one hand, from Equation (1) and with regard to Equations (3) and (5), it follows that
This contradiction proves that Equation (1) can not have two different almost periodic solutions. ☐
Theorem 2. If the right-hand side of Equation (1) for each fixedis a function convex in, and there exists a momentsuch thatis strictly convex, then the Equation (1) can have no more than two almost periodic solutions.
Proof. Suppose that the conditions of the theorem are satisfied, and, conversely, Equation (1) has three almost periodic solutions
,
starting at the points
,
,
for
. In the proof of Theorem 2 [
32], it is shown that in the considered situation Equation (1) has the property of existence and uniqueness of solutions, and therefore it is assumed that for all
Consider two obvious identities, which hold for all
in view of Equation (6):
and
Consider an arbitrary
. As noted in the proof of Theorem 1, it can assumed that
. Let these equalities be integrated in the limits from
to
. Then,
and
Subtracting the second equality from the first one, it follows that
Let the solution
be represented in the following form:
By Equation (6) it is obvious that
for all
. Substituting the representation of Equation (8) into Equation (7), the following is obtained:
Repeating the arguments presented in the proof of Theorem 2 [
32], it is easy to verify that:
while the definition of the function
as well as convexity with respect
of the function
imply that, for any
,
Besides,
.
Consider the functions
and
once again. It is clear from their definition that they are almost periodic and that
Consider some
and
such that
Existence of such
follows from existence of common
-almost period for functions
and
[
35].
Then, taking into account the properties of the function
indicated above for
taken from (9) it follows that
On the other hand,
so that this contradiction proves the assertion of the theorem.
The next step is to prove the theorem similar to Theorem 3 [
32]. Therefore, it is further assumed that the right-hand side of equation
is a function continuous on
that has a continuous on
derivative with respect to
,
that is convex in
for to each fixed
, and there exists a moment
such that
is strictly convex with respect to
. As given above, the solution of Equation (10) starting for
at the point
is denoted by
, and assume that
☐
Theorem 3. Assume Equation (10) has two bounded solutionsand, and letbe two points fromsuch thatandare uniformly bounded. Then a set of functions, is uniformly bounded.
Proof. The equation in variations implies that
which implies the uniform boundedness below of the functions
,
.
Let us show that the functions
,
, are bounded uniformly from above. Consider an arbitrary point
. It follows from the proof of Theorem 3 [
32] that a function
is convex on
for any finite
. Hence, representing
in the form
gives the following:
Potentiating this inequality and subsituting
by
and
by
the following is obtained:
Taking into account the arbitrariness of and it becomes obvious that the functions , are uniformly bounded from the above.
Thus, the set of functions , is uniformly bounded from the above and below, so that it is uniformly bounded. ☐
Theorem 4. If the conditions of Theorem 3 are satisfied, then the set of functions, is uniformly bounded and equicontinuous with respect to.
Proof. The uniform boundedness of the functions , is provided by the uniqueness property of Equation (10) solutions and the assumption that the solutions and are bounded. Their equicontinuity property is caused by the uniform boundedness of the functions , , proven in Theorem 3. ☐
Theorem 5. Let Equation (10) have two bounded solutionsand, is unbounded for some. Then there exists an intervalsuch thatis unbounded for any, and for any sequence, as, for whichas, it is possible to extract a subsequencesuch the sequence of functionswould tend to infinity uniformly with respect toas.
Proof. Consider a sequence
,
as
such that
as
. Let some
be fixed, then consider the sequence of functions
,
. If this sequence of functions tends to infinity uniformly with respect to
as
, then interval
is the desired one. Otherwise, there exist
and a sequence
such that
Consider an arbitrary point
and suppose that
Consider now arbitrarily large
and
being so large that for all
Due to the convexity of the function
, for any finite
,
And from the continuity of the function
and the fact that for
and
it follows that for all
and therefore for all
Taking this into account, for any
and any
it follows that
i.e., for any
and for all
The arbitrariness of implies that on the functions as well as tend uniformly with respect to to infinity as . Thus, is a desired interval.
The presented theorem proves the following assertion. ☐
Theorem 6. If Equation (10) has two bounded solutionsand, then for anyfunctionis bounded.
Proof. Suppose, on the contrary, that in , there exists a point for which is unbounded. Then, by Theorem 5, there exists a sequence , as and interval , such that functions tend to infinity as uniformly with respect to .
Consider two points
and
in
and consider the difference
. By the Lagrange theorem, for any
where
. The right-hand side of this equality is unbounded due to the uniform with respect to
convergence of the functions sequence
to infinity. Hence its left-hand side is also unbounded. But then, in view of the uniqueness of the Equation (10) solutions, there must be at least one of the unbounded functions
or
, which contradicts the assumption of their boundedness. This contradiction proves that in
there is no point
at which the function
would be unbounded.
If we further assumes that Equation (10) has four almost periodic solutions , . Since every almost periodic function is bounded, in the case under consideration all the theorems proved above remain valid.
Consider an arbitrary sequence
,
as
,
. Let
denote an
-almost period of functions
,
. Such
exists, since for a finite number of almost periodic functions for any
, there exists a common
-almost period [
35]. Without loss of generality, it can be assumed that
as
. ☐
Theorem 7. If Equation (10) has four almost periodic solutions, , then a set of functions, is uniformly bounded for any interval.
Proof. Consider an arbitrary interval . By Theorem 6, the functions and are bounded, but then a set of functions , is uniformly bounded by Theorem 3, which implies a uniform boundedness from above of a functions set , . Thus, in order to verify the validity of the assertion given in the theorem, it must be proved that a set of functions , is uniformly bounded from below.
The proof of this assertion involves two steps: it must be proven first that the sequence is bounded from below for any , and then the uniform boundedness of functions on the interval .
The proof of the boundedness from below of the sequence for any is hold by contradiction. Let there exist for which the sequence is unbounded from below. First of all, it must be proven that in this case, the sequence is unbounded from below for any .
Consider the contrary. Then there exists a point
for which the sequence
is bounded. Let, for definiteness,
. Then, by the convexity of the function
,
, for any
,
where
. If
is unbounded from below, then the right-hand side of this inequality is unbounded below as the sum of two functions unbounded from below, and if
is bounded from below, then the right-hand side of the inequality under consideration is unbounded below as the sum of functions bounded and unbounded from below, since as it is proved before,
is bounded from above. Thus, the right-hand side of the inequality considered is unbounded from below in any of the two possible cases. So that, its left-hand side is also unbounded from below, which contradicts the assumption that
is bound from below. The case when
can be considered in a similar way.
Thus, if the sequence
is unbounded for some
, then for all
the sequence
is also unbounded from below. But then it follows from the definition of
that, for any
,
Moreover, this convergence is uniform on any interval
. The last remark is valid in view of the estimate obtained in the proof of Theorem 3,
valid for all
and
.
Suppose
,
. Then, on
, the sequence of functions
converges uniformly to a function constant on
. Then,
But the specific choice of
implies that
Hence . This contradiction proves that the sequence is bounded from below for any .
Now it must be proved that a set of functions
is uniformly bounded from below on
. Consider two points
from
. Then, for any
, due to convexity of the function
on
, it follows that for
,
Considering that
and that the left-hand side of inequality presented above is bounded from below by a constant for all
, the required conclusion is obtained.
Thus, it is shown that functions taken on an arbitray interval are uniformly bounded both from above and below, and therefore are uniformly bounded. ☐
Theorem 8. If Equation (10) has four almost periodic solutions, , then the functions, are equicontinuous for any interval.
Proof. Consider an arbitrary interval
and two points
in it. Assume:
Since
is a function convex on
, then the function
,
is increasing with respect to
for any
[
3]. Then,
In Theorem 7 it is shown that the sequence
is bounded, and that the functions
are uniformly bounded for
. Taking this into account, the following inequality is obtained:
which holds for all
.
It can be proved in a similar way that there exists a finite
such that for all
and any
and
in
Consider now an arbitrary
and assume that
Then for all
and any
and
from
such that
,
This proves that the functions are equicontinuous on an arbitrarily taken interval .
Without loss of generality, it can assumed that the function
on the right-hand side of Equation (10) is such that
for it, where
is the moment at which the function
is strictly convex with respect to
. Then, it follows from the proof of Theorem 3 [
32] that the functions
are strictly convex on
for all
for which
. Theorems 7 and 8 prove that the sequence of functions
satisfies all the requirements of the Arzela–Ascoli theorem at an arbitrarily taken interval
. Hence, this sequence can be assumed to be uniformly convergent to a continuous function
on
. Note that starting from some number
all functions
are strictly convex for
. ☐
Theorem 9. If Equation (10) has four almost periodic solutions, then the sequence of functionsconverges to a strictly convex functionon any interval.
Proof. Since the functions
are convex and uniformly convergent on an arbitrarily chosen interval
, the function
is convex on
. If
is assumed to be not strictly convex, then there exists an interval
for which
where
and
are constants. Consider now the functions
on an interval
.
Consider also four points in
and the right derivative of function
. This derivative exists and is finite by convexity of
.
It follows from Theorem 12 [
31] that there exist two sequences
and
such that
,
for all
and the following inequalities are realised:
and
Taking into account that for each
the following is obtained:
Moreover, since for any
,
then for
Moreover, this convergence is uniform with respect to .
Let
be an arbitrary right derived number of the function
at a point
, and let
be the sequence on which this derived number is realized for
as
,
. Let us fix some
. Then for any natural number
Then
where
is a sufficiently small constant, and
Repeating the arguments given in the proof of Theorem 3 [
32], it is easy to prove that
strictly increases on
. Then it can be represented as
where
is a continuous function, and
is a function of the function
jumps. It is easy to verify that
strictly increases on
, and for any
Consider now the function
It follows from the estimates obtained above that all the right derived numbers of a function
for any finite
are nonnegative, and the function
itself does not have jumps down, since
increases, and
is continuous. Hence, taking into account the Theorem 9 proposition in [
33], it can be concluded that for each finite
the function
increases with respect to
. So that,
has a derivative almost everywhere in
. Let us define
for all points
, assuming that
at those points
in which
has no derivative.
For a function
defined in this way and for any finite
, the following inequality is realised:
Taking into account the definition of the function
, it can be obtained from the inequality given above that for any finite
which contradicts the existence of identical limits for these two sequences. Note that the inequality
follows from the strict increase of the function
on
.
Thus, it is shown that there is no segment on which the function coincides with a line segment, and, consequently, is strictly convex on any interval .
So now a theorem analogous to Theorem 3 can be proven [
32]. ☐
Theorem 10. Equation (10) can not have more than three almost periodic solutions.
Proof. Let Equation (10) have four almost periodic solutions
,
. Then consider three sequences
,
Since they are bounded, they can be considered convergent without loss of generality. Suppose that
Let us prove now that for any . Let, for example, . Then consider an arbitrary interval . By Theorem 6, the functions and are bounded, so that on the basis of Theorem 4 it can be concluded that a set of functions , is uniformly bounded and equicontinuous with respect to . Taking into account Theorems 3 and 8, it follows that the sequence of functions , is also uniformly bounded and equicontinuous with respect to . Considering this fact, without loss of generality, the sequences of functions and , can be considered uniformly convergent to continuous functions and , respectively.
The assumption that
implies that on
and then
It follows from the last identity that on
,
But this is impossible, since is strictly convex on any closed interval belonging to due to Theorem 9. This contradiction proves that can not be equal to zero. For the remaining two intervals, the arguments are similar.
From the fact that
,
it follows there exist
such that for all
:
Consider
being so large that for all
and all
and
the following relations hold:
Let us fix an arbitrary
. Then, by virtue of
choice, the function
reaches its maximum at some internal point of this interval on each of the intervals
,
. Therefore, in each interval
,
there exists a point
such that
Then, considering that
the following is obtained:
So, if Equation (10) has four almost periodic solutions, then for some sufficiently large
there exist three different points
on
, each of which satisfies in each of which
But for and , the function is strictly convex, and it consequently, can not take three identical values in . This contradiction proves that the assumption can not be realized.
The main results obtained here can be represented in a unified form, for which the new notation is introduced setting that
where
is a function that is continuous in a set of arguments. ☐
Theorem 11. If for somea functionis continuous in the set of arguments and convex with respect tofor each fixed, and there exists a momentsuch thatis strictly convex, then Equation (1) can have no more thanalmost periodic solutions.
3. A Lower Bound for the Number of Almost Periodic Solutions
On the basis of the previous theorems, the authors obtain the conditions to determine the maximum possible number of almost periodic solutions in first-order differential equation. Now the problem of the existence of almost periodic solutions for the equation is under consideration, since this allows for the determination of the minimum possible number of almost periodic solutions for the differential equation considered.
So, consider the first-order differential equation
where
is a function continuous on
that is almost periodic in
uniformly in
in every compact set and such that Equation (11) has the property of existence and uniqueness of its solutions.
To prove the existence of almost periodic solution for Equation (11), the result obtained in [
35] should be used. Let it be formulated in the form of the following theorem.
Theorem 12. Let the right-hand side of Equation (11) be such thatdecreases with respect tofor each fixed. Then, if Equation (11) has a bounded solutionsuch thatthen it has an almost periodic solutionwhose range of values is in the interval.
Remark 1. If in Equation (11) veriable change is realized, setting , then the following equation is obtained: It is clear that if Equation (11) has an almost periodic solution, then Equation (12) also has an almost periodic solution, and vice versa. This implies that Theorem 12 is valid if increases with respect tofor each fixed.
Theorem 13. If the right-hand side of Equation (11) is a function decreasing with respect tofor each fixed, andanduniformly with respect to , then Equation (11) has an almost periodic solution. Proof. By virtue of the assumption that
as
and
as
uniformly with respect to
, there exist constants
and
, such that for
and for
Therefore, the solution of Equation (11) starting at any point , can not leave the band . Thus, Equation (11) has a bounded solution, which implies that Equation (11) has at least one almost periodic solution taking into account Theorem 12. ☐
Theorem 14. Letdecrease with respect tofor each fixed, and there exists a moment, such thatstrictly decreases. Then, in order for Equation (11) to have a unique, almost periodic solution, it is necessary and sufficient that it has at least one bounded solution.
Proof. The necessity of the theorem conditions is obvious, since if Equation (11) has an almost periodic solution, then this solution is the desired bounded solution. Let the sufficiency be proven. ☐
If Equation (11) has a bounded solution, then the requirements of Theorem 12 hold, which implies that Equation (11) has an almost periodic solution. But, by Theorem 1, Equation (11) can not have more than one almost periodic solution if the conditions of Theorem 14 are satisfied. Integration of these two assertions implies that Equation (11) has a unique almost periodic solution due to the conditions of Theorem 14.
Theorem 15. Let the right-hand side of Equation (11) be such that the equationhassolutions,
,
with the following property: for any,
1…,
in the domainwhere it is supposed,
,
the functionis constant-sign, and the sign of the function changes when passing to the neighboring domain. Then, ifand in each domainthe functionis increasing or decreasing with respect tofor each fixed,
then Equation (11) hasalmost periodic solutions. Proof. First of all, let us prove that if there exists bounded functions defined on
continuously differentiable functions
α(
t) and
, such that
and
then Equation (11) has a bounded solution.
Suppose that
and consider the equation
It is clear that Equation (13) turns into Equation (11) if Equation (11) has a solution
, such that for all
Let us prove that such a solution exists.
Consider the contrary. Then, the solution
, starting at an arbitrary point
, leaves the considered domain in time. For example, let it get into the domain
. For this opportunity to be realizable, there must necessarily exist a point
at which
and
. In this case, from (13), the following is obtained:
However,
and by condition
therefore,
Thus, the left-hand side of Equation (14) does not exceed zero, and its right-hand side is strictly greater than zero for .
This contradiction shows that the solution
of Equation (13) starting at a point
can not get into the domain
. Similarly, it can be proven that this solution also can not get into the domain
. Therefore, for
the following estimation is realized:
which implies that there exists a bounded solution for Equation (13) and for Equation (11) as well, considering the assumption thst the functions
and
are bounded.
The case when
can be considered in a similar way.
Now consider an arbitrary
. Assume for definiteness that in the domain
and in the domain
By the condition of the theorem
Therefore, for the considered
for
and for
Thus, all the requirements of the proved statement hold, which allows us to conclude that Equation (11) has a bounded solution in the band
However, by assumption, the function
is monotonous and almost periodicwith respect to
uniformly in
in this band, i.e., in the band
all the requirements of Theorem 12 are satisfied, which implies that Equation (11) has an almost periodic solution in the band
Let us prove that in the band
there can not exist two almost periodic solutions. Suppose the contrary. Let
denote one almost periodic solution, and
denote the other. Let, for definiteness,
. Let the difference
be represented in the form
and
never intersect due to existence and uniqueness of the solutions, so that for all
:
It is obvious that in the band:
the function
decreases with respect to
for each fixed
. Therefore, for all
Taking this into account, the following inequality can be concluded:
In order to be an almost periodic solution
must necessarily get from the domain above the curve
into the domain under the curve
. This means that there exists a time point
, such that
But by the theorem condition
and a graph
of the function is a boundary of the sign change domains of the function
. Consequently, at the point the following inequality holds:
Since the function is continuous, this inequality implies that in (15), the inequality is strict for .
Let us show that this contradicts the assumption that the solutions
and
are almost periodic. Indeed, the difference of two almost periodic functions is an almost periodic function. Consider a sequence of positive numbers
decreasing to zero and the sequence
corresponding to it. Here
is a
-almost period of function
. Without the loss of generality, the sequence
can be considered as tending to infinity as
. Consider
such that
. Then for all
which contradicts the choice of the sequence
. This contradiction proves that in the band
there is only one almost periodic solution of Equation (11).
But there are such bands, by the condition of the theorem, which implies that Equation (11) has almost periodic solutions when the conditions of Theorem 15 are satisfied. ☐