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An exact expression of positive periodic solution for a first-order singular equation
Advances in Difference Equations volume 2020, Article number: 532 (2020)
Abstract
The main purpose of this paper is to obtain an exact expression of the positive periodic solution for a first-order differential equation with attractive and repulsive singularities. Moreover, we prove the existence of at least one positive periodic solution for this equation with an indefinite singularity by applications of topological degree theorem, and give the upper and lower bounds of the positive periodic solution.
1 Introduction
A variety of population dynamics and physiological processes can be described by the following singular differential equation:
with periodic boundary value condition
where \(a(t)\) and \(b(t)\in C(\mathbb{R},\mathbb{R})\) are ω-periodic functions, ρ and ω are positive constants. According to the literature [1–3], we say that Eq. (1.1) has an attractive singularity if \(b(t)<0\), repulsive singularity if \(b(t)>0\) and indefinite singularity if \(b(t)\) may change sign. Moreover, we say that Eq. (1.1) has a strong singularity if \(\rho\geq1\) and a weak singularity if \(0<\rho<1\).
As is well known, singular equations have a wide range of applications in many fields, and the existence of positive ω-periodic solutions to singular equations plays a significant role in solving many practical problems. There is a good amount of work on periodic solutions for singular equations (see [4–18] and the references cited therein). In 2003, Agarwal and O’Regan [4] provided some results on positive ω-periodic solutions of Eq. (1.1), where \(b(t)>0\) (i.e., repulsive singularity). After that, Chu and Nieto [10] in 2008 proved the existence of positive ω-periodic solutions for equation (1.1) with repulsive singularity and impulses by applications of Leray–Schauder alternative principle. Recently, Wang [15] and Chen et al. [7] discussed the existence of positive ω-periodic solutions for the following singular differential equation:
where \(a_{1}(t)\) and \(b_{1}(t)\in C(\mathbb{R},[0,+\infty))\) are ω-periodic functions with \(\int^{\omega}_{0}a_{1}(t)\,dt>0\) and \(\int^{\omega}_{0}b_{1}(t)\,dt>0\), the nonlinear term f has an attractive singularity or repulsive singularity. Their proofs were based on Krasnoselskii’s fixed point theorem in a cone, the Leray–Schauder degree and the upper and lower solutions method.
It is worth pointing out that the above results are only related to the existence of positive ω-periodic solutions of first-order differential equations with attractive singularity or repulsive singularity, but the exact expression of ω-periodic solutions is not involved.
First, in this paper we give an exact expression of positive ω-periodic solution for Eq. (1.1) with attractive and repulsive singularities.
Theorem 1.1
Assume that condition \(\int^{\omega}_{0}a(t)\,dt\cdot b(t)>0\)holds. Then Eq. (1.1) has a unique positive ω-periodic solution \(x(t)\), which can be written as
Second, from the condition \(\int^{\omega}_{0}a(t)\,dt\cdot b(t)>0\), it is easy to verify that the weight term \(b(t)\) has a non-changing sign. A natural question is how Eq. (1.1) works on changing sign of \(b(t)\) (i.e., indefinite singularity)? We also consider the existence of positive ω-periodic solution for equation (1.1) with an indefinite singularity.
Theorem 1.2
Assume that \(\bar{a}:=\frac{1}{\omega}\int^{\omega}_{0}a(t)\,dt>0\)and \(\bar{b}:=\frac{1}{\omega}\int^{\omega}_{0}b(t)\,dt\geq0\)hold. Furthermore, suppose the following conditions are satisfied:
- (\(H_{1}\)):
-
\(1-\frac{\|a\|\omega(\rho+1)}{2}>0\), here \(\|a\|:=\max_{t\in[0,\omega]}|a(t)|\);
- (\(H_{2}\)):
-
\(\frac{\bar{b}}{\overline{a_{+}}}-\frac{\omega(\rho+1)(\|a\| \overline{b_{+}}+\|b\|\bar{a})}{\bar{a}(2-\|a\|\omega(\rho+1))}>0\), here \(a_{+}(t):=\max\{0,a(t)\}\).
Then Eq. (1.1) has at least one positive ω-periodic solution \(x(t)\)with
2 Proof of Theorem 1.1
In this section, an exact expression of solution for Eq. (1.1) with periodic boundary value condition is given.
First, we change the variable \(x=u^{\alpha}\), where \(\alpha=\frac {1}{\rho+1}\) and \(0<\alpha<1\). Then Eq. (1.1) is converted into the following form:
with periodic boundary value condition
Proof of Theorem 1.1
Applying method of variation of constant, solution of Eq. (2.1) can be written as the following form:
where \(C(t)\in C(\mathbb{R},\mathbb{R})\). Substituting Eq. (2.2) into Eq. (2.1), we arrive at
Integrating the above equation over the interval \([0,t]\), here \(t\in[0,\omega]\), we get
Furthermore, we give
Since \(u(0)=u(\omega)\), we obtain
Combining Eqs. (2.4) and (2.5), we have
Then we get
Therefore, the solution of Eq. (2.1) is
Because \(x(t)=u^{\alpha}(t)\) and \(\alpha=\frac{1}{\rho+1}\), the solution of Eq. (1.1) is
From the condition \(\int^{\omega}_{0}a(t)\,dt\cdot b(t)>0\), it is easy to see that \(x(t)\) is positive for all \(t\in\mathbb{R}\). The proof is completed. □
Example 2.1
Consider the following first-order singular differential equation:
Comparing Eq. (2.7) with Eq. (1.1), we see that \(a(t)=\sin t+1\), \(b(t)=e^{3\cos t}\), \(\rho=2\), \(\omega=2\pi\). Furthermore, the condition
is satisfied. Using Eq. (2.6), we calculate the solution of Eq. (2.7) to be
and \(x(t)\) is 2π-periodic. Substituting Eq. (2.8) into Eq. (2.7), we conclude that \(e^{\cos t}\) is a solution of Eq. (2.7).
3 Proof of Theorem 1.2
For convenience, we recall the topological degree theorem by Mawhin [19].
Lemma 3.1
(see [19, Theorem 2.4])
Let X, Z be real normed spaces and \(L: D(L)\subset X\rightarrow Z\)a linear Fredholm map of index zero. Assume that \(\Omega\subset X\)is an open bounded set and \(N: \overline{\Omega}\rightarrow Z\)is an L-compact mapping. Furthermore, assume that the following conditions are satisfied:
-
(i)
\(Lx+\lambda Nx\neq0\), for each \((x,\lambda)\in [(D(L)\setminus\ker L)\cap\partial\Omega]\times(0,1)\);
-
(ii)
\(Nx\notin\operatorname{Im} L\), for each \(x\in\ker L\cap \partial\Omega\);
-
(iii)
\(D_{0}(QN\mid_{\ker L},\Omega\cap\ker L)\neq0\), where \(Q: Z\rightarrow Z\)is a continuous projector such that \(\ker Q=\operatorname{Im} L\)and \(D_{0}\)is the Brouwer degree.
Then the equation \(Lx+Nx=0\)has at least one solution in \(D(L)\cap \overline{\Omega}\).
Proof of Theorem 1.2
Define \(X:=\{x\in C(\mathbb{R}, \mathbb{R}), x(t+\omega)\equiv x(t), \forall t\in\mathbb{R}\}\) endowed with the \(C^{1}\)-norm, \(Z=L^{1}([0,\omega], \mathbb{R})\) with the \(L^{1}\)-norm. Let \(D(L)\) = {\(x\in X: x'\) is absolutely continuous on \(\mathbb{R}\)}, we define operators \(L: D(L)\rightarrow Z\) and \(N: Z\rightarrow Z\) by
Form this, Eq. (1.1) can be converted to \(Lx+Nx=0\). Define projectors \(P: X\rightarrow X\) and \(Q: Z\rightarrow Z\) by
As literature [20, Theorem 1.1], it is easy to verify that L is a Fredholm linear mapping with zero index and for any open bounded set \(\Omega\subset X\), N is L-compact on Ω̅.
Consider the following homotopy family of Eq. (1.1):
which can be expressed as the abstract equation \(Lx+\lambda Nx=0\).
Multiplying both sides of Eq. (3.2) with \(x^{\rho}(t)\) and integrating over the interval \([0,\omega]\), we get
which yields
Thus, there exists a point \(\eta\in[0,\omega]\) such that
Since \(\bar{b}\geq0\), we obtain
Meanwhile, Eq. (3.2) together with the fact of \(x(t)>0\) gives
Integrating the above equation over the interval \([0,\omega]\), we get
which yields
Thus, there exists a point \(\xi\in[0,\omega]\) such that
Since \(\bar{a}>0\), we arrive at
Let \(x=u^{\alpha}\), where \(\alpha=\frac{1}{\rho+1}\), Eqs. (3.2), (3.3) and (3.4) can be turned into
It follows from Eqs. (3.6) and (3.7) that
Similarly, we deduce
Multiplying both sides of Eq. (3.5) with \(u'(t)\) and integrating it over the interval \([0,\omega]\), we get
From Eq. (3.9) and the Hölder inequality, the above equation implies
It follows from condition (\(H_{1}\)) and the above inequality that
Using Eqs. (3.8), (3.9) and (3.10), we obtain
since condition (\(H_{2}\)). Moreover,
Therefore, we obtain
and
Define
where \(0< E_{1}< M_{1}\), \(E_{2}>M_{2}\). Then conditions (i) and (ii) of Lemma 3.1 are verified. For a constant \(x\in\ker L\), \(x>0\), we have
It follows from Eqs. (3.3), (3.4), (3.11) and (3.12) that
Therefore, we obtain
Thus condition (iii) of Lemma 3.1 holds. Therefore, \(Lx+Nx=0\) has at least one solution in \(\overline{\Omega}_{1}\), which means Eq. (1.1) has at least one positive ω-periodic solution \(x(t)\) with
□
Example 3.1
Consider the following first-order differential equation with an indefinite singularity:
Comparing Eq. (3.13) with Eq. (1.1), we see that \(a(t)=\frac{1}{16}\cos(16t)+\frac{1}{32}\), \(b(t)=\frac{1}{32}\sin (16t)+\frac{\sqrt{3}}{64}\), \(\rho=3\), \(\omega=\frac{\pi}{8}\). By calculating, we get
It can be verified that conditions (\(H_{1}\)) and (\(H_{2}\)) are satisfied. Using Theorem 1.2, we see that Eq. (3.13) has at least one positive \(\frac{\pi}{8}\)-periodic solution \(x(t)\) with
4 Conclusions
In this paper, applying method of variation of constant, we obtain an exact expression of positive periodic solution for equation (1.1) with attractive and repulsive type. After that, we prove the existence of at least one positive periodic solution for Eq. (1.1) with an indefinite singularity by applications of topological degree theorem, and give the upper and lower bound of the positive periodic solution.
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Acknowledgements
YX, XXC, JL are grateful to anonymous referees for their constructive comments and suggestions which have greatly improved this paper.
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This work was supported by Research is supported by Key Research Funds for the Universities of Henan Province (19A110018, 20B110006), Fundamental Research Funds for the Universities of Henan Province (NSFRF170302, NSFRF180320), Henan Polytechnic University Doctor Fund (B2016-58).
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YX, XXC, JL contributed equally and significantly in writing this article. All authors read and approved the final manuscript.
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Xin, Y., Cui, X. & Liu, J. An exact expression of positive periodic solution for a first-order singular equation. Adv Differ Equ 2020, 532 (2020). https://doi.org/10.1186/s13662-020-02986-2
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DOI: https://doi.org/10.1186/s13662-020-02986-2