Periodic solutions for a kind of neutral functional differential systems

In this paper, we analyze some properties of the linear difference operator $A:C_T\to C_T$, $[Ax](t)=x(t)-V(t)x(t-\tau )$, and then, by using the coincidence degree theory of Mawhin, a kind of neutral differential systems with non-constant matrix is studied. Some new results on the existence of periodicity are obtained. It is worth noting that $V(t)$ is no longer a constant matrix, which is different from the corresponding ones of past work.

The field of neutral functional equations (in short NFDEs) is making significant breakthroughs in its practice; it is no longer only a specialist’s field. In many practical systems, models of systems are described by NFDEs in which the models depend on the delays of state and state derivatives. Practical examples for neutral systems include population ecology, heat exchanges, mechanics, and economics; see [1]–[4]. In particular, qualitative analysis such as periodicity and stability of solutions of NFDEs has been studied extensively by many authors. We refer to [5]–[12] for some recent work on the subject of periodicity and stability of neutral equations.

In the last few years, the stability of neutral systems of various classes with time delays has received an ever-growing interest from many authors. Many sufficient conditions have been proposed to guarantee the asymptotic stability for neutral time delay systems. We only mention the work of some authors [13]–[15]. It is well known that the existence of periodic solutions of neutral equations and neutral systems is a very basic and important problem, which plays a role similar to stability. Thus, it is reasonable to seek conditions under which the resulting periodic neutral system would have a periodic solution. Much progress has been seen in this direction and many criteria are established based on different approaches. However, there is no paper for investigating the existence of periodic solutions of neutral system with non-constant matrix. In addition, to the best of our knowledge, most of the existing results deal with scalar NFEDs or neutral systems with a constant matrix. For example, in papers [16]–[20], based on Mawhin’s continuation theorem, several types of scalar neutral equations have been studied:

For a neutral system, we note that Lu and Ge [21] studied the following system:

But C is a constant symmetric matrix. The purpose of this paper is to investigate the existence of periodic solutions to the nonlinear neutral system with non-constant matrix of the form

where $x\in {\mathbb{R}}^n$, $C(t)=diag(c_1(t),c_2(t),\dots ,c_n(t))$, $C(t+T)=C(t)$; $F(x)\in C^2({\mathbb{R}}^n,\mathbb{R})$, $G(x)\in C^1({\mathbb{R}}^n,\mathbb{R})$; $p\in (\mathbb{R},{\mathbb{R}}^n)$, $p(t+T)=p(t)$; $\gamma \in C(\mathbb{R},\mathbb{R})$, $\gamma (t+T)=\gamma (t)$; T, and τ are given constants with $T>0$.

Throughout this paper, we use some notation:

1. (1)

   $I_n=\{1,2,\dots ,n\}$; $\mathrm{\forall }a={(a_1,a_2,\dots ,a_n)}^T\in {\mathbb{R}}^n$, $|a|={({\sum }_{i=1}^n{|a_i|}^2)}^{\frac{1}{2}}$;

2. (2)

   $C_T=\{x:x\in C(\mathbb{R},{\mathbb{R}}^n),x(t+T)=x(t),\mathrm{\forall }t\in \mathbb{R}\}$ with the norm

   $${|\phi |}_0=\underset{t\in [0,T]}{max}|\phi (t)|,\mathrm{\forall }\phi \in C_T;$$

1. (3)

   $C_T^1=\{x:x\in C^1(\mathbb{R},{\mathbb{R}}^n),x(t+T)=x(t),\mathrm{\forall }t\in \mathbb{R}\}$ with the norm

   $$\parallel \phi \parallel =\underset{t\in [0,T]}{max}\{{|\phi |}_0,{\left|{\phi }^{\prime }\right|}_0\},\mathrm{\forall }\phi \in C_T^1.$$

Clearly, $C_T$ and $C_T^1$ are Banach spaces.

Lemma 2.1

[22]

If$|c(t)|\ne 1$, then operator$A_1$has a continuous inverse$A_1^{-1}$on$C_T$, satisfying

Here

Let

where$\mathrm{\forall }t\in \mathbb{R}$, $V(t)\in C_T^1$is a real symmetric matrix.

We will give some properties of $\mathcal{A}$.

Lemma 2.2

Suppose that${\lambda }_1(t),{\lambda }_2(t),\dots ,{\lambda }_n(t)$are eigenvalues of$V(t)$. Then the operator$\mathcal{A}$has continuous inverse${\mathcal{A}}^{-1}$on$C_T$, satisfying

where

Proof

1. (1)

   Since $V(t)$ is a real symmetric matrix, there exists an orthogonal matrix $U(t)$ such that

   $$U(t)V(t)U^T(t)=E_{\lambda }(t)=diag({\lambda }_1(t),{\lambda }_2(t),\dots ,{\lambda }_n(t)).$$

Consider the system

where we have equivalence to

where $\tilde{f}(t)=U(t)f(t)$, $y(t)=U(t)x(t)$. On the other hand, a component of the vector in system (2.1) is

From Lemma 2.1, we have

Thus, ${\mathcal{A}}^{-1}$ exists and

When ${\lambda }_{i,L}<1$, by (2.2) we get

i.e.,

Thus, by (2.3) we have

Obviously,

1. (2)

   Similar to the above proof, when ${\lambda }_{i,l}>1$, we get

   $$\begin{array}{r}{\left|{\mathcal{A}}^{-1}f\right|}_0\le {\left(\sum _{i=1}^n\frac{1}{{(1-{\lambda }_{i,l})}^2}\right)}^{\frac{1}{2}}{|f|}_0,\\ {\int }_0^T|{\mathcal{A}}^{-1}f(t)|dt\le {\left(\sum _{i=1}^n\frac{1}{{(1-{\lambda }_{i,l})}^2}\right)}^{\frac{1}{2}}{\int }_0^T|f(t)|dt.\end{array}$$

 □

Let X and Y be two Banach spaces and let $L:D(L)\subset X\to Y$ be a linear operator, a Fredholm operator with index zero (meaning that ImL is closed in Y and $dimKerL=codimImL<+\mathrm{\infty }$). If L is a Fredholm operator with index zero, then there exist continuous projectors $P:X\to X$, $Q:Y\to Y$ such that $ImP=KerL$, $ImL=KerQ=Im(I-Q)$, and $L_{D(L)\cap KerP}:(I-P)X\to ImL$ is invertible. Denote by $K_p$ the inverse of $L_P$.

Let Ω be an open bounded subset of X, a map $N:\overline{\mathrm{\Omega }}\to Y$ is said to be L-compact in $\overline{\mathrm{\Omega }}$ if $QN(\overline{\mathrm{\Omega }})$ is bounded and the operator $K_p(I-Q)N(\overline{\mathrm{\Omega }})$ is relatively compact. We first give the famous Mawhin continuation theorem.

Lemma 2.3

[23]

Suppose that X and Y are two Banach spaces and$L:D(L)\subset X\to Y$is a Fredholm operator with index zero. Furthermore, $\mathrm{\Omega }\subset X$is an open bounded set and$N:\overline{\mathrm{\Omega }}\to Y$is L-compact on$\overline{\mathrm{\Omega }}$. If all the following conditions hold:

1. (1)

   $Lx\ne \lambda Nx$, $\mathrm{\forall }x\in \partial \mathrm{\Omega }\cap D(L)$, $\mathrm{\forall }\lambda \in (0,1)$,

2. (2)

   $Nx\notin ImL$, $\mathrm{\forall }x\in \partial \mathrm{\Omega }\cap KerL$,

3. (3)

   $deg\{QN,\mathrm{\Omega }\cap KerL,0\}\ne 0$,

then the equation$Lx=Nx$has a solution on$\overline{\mathrm{\Omega }}\cap D(L)$.

Theorem 3.1

Suppose that${\int }_0^{T}p(t)dt=0$, $\phi (t)$is a nonzero periodic solution of (3.1) and there exists a constant$M>0$such that

(H₁):$\mathrm{\forall }i\in I_n$, $\frac{\partial G}{\partial x_i}$is bounded in the set${\mathrm{△}}_1$ (or${\mathrm{△}}_2$), where

(H₂):$x_i\frac{\partial G}{\partial x_i}>0$ (or <0), whenever$|x_i|>M$, $i\in I_n$.

(H₃):Suppose that${\mu }_1,{\mu }_2,\dots ,{\mu }_n$are eigenvalues of$\frac{{\partial }^{2}F(v)}{\partial x^2}$, $v\in {\mathbb{R}}^n$, and there exists a constant${\lambda }_F\ge 0$such that

Then system (1.1) has at least one T-periodic solution, if${\lambda }_{0,i}<\frac{1}{2}$ (or${\sigma }_{0,i}>1$), $({\lambda }_{2,i}Tn+n{\lambda }_{1,i}\sqrt{n})T+{\lambda }_{0,i}<1$, and$\tau =mT$, $m\in \mathbb{Z}$, where

Proof

Define

where $D(L)=\{x:x\in C_T^1,x^{″}\in C(\mathbb{R},{\mathbb{R}}^n)\}$. Then system (1.1) obeys the operator equation $Lx=Nx$. We have ${(x(t)-C(t)x(t-\tau ))}^{″}=0$, $\mathrm{\forall }x\in KerL$. Then

where ${\tilde{c}}_1,{\tilde{c}}_2\in {\mathbb{R}}^n$. Since $x(t)-C(t)x(t-\tau )\in C_T$, we have ${\tilde{c}}_1=0$. Let $\phi (t)\in C(\mathbb{R},{\mathbb{R}}^n)$ be a nonzero periodic solution of

then ${|\phi (t)|}^2>0$ and ${\int }_0^T{\phi }^2(t)dt\ne 0$, where I is an unit matrix. We get

Obviously, ImL is closed in $C_T$ and $dimKerL=codimImL=n$. So L is a Fredholm operator with index zero. Define continuous projectors P, Q:

and

Let

then

Since $ImL\subset C_T$ and $D(L)\cap KerP\subset C_T^1$, $K_P$ is an embedding operator. Hence $K_P$ is a completely continuous operator in ImL. By the definitions of Q and N, one knows that $QN(\overline{\mathrm{\Omega }})$ is bounded on $\overline{\mathrm{\Omega }}$. Hence the nonlinear operator N is L-compact on $\overline{\mathrm{\Omega }}$. We complete the proof by three steps.

Step 1. Let ${\mathrm{\Omega }}_1=\{x\in D(L)\subset C_T^1:Lx=\lambda Nx,\lambda \in (0,1)\}$. We show that ${\mathrm{\Omega }}_1$ is a bounded set. We have $Lx=\lambda Nx$$\mathrm{\forall }x\in {\mathrm{\Omega }}_1$, i.e.,

Integrating both sides of (3.2) over $[0,T]$, we have

i.e., $\mathrm{\forall }i\in I_n$,

Let $\frac{\partial G}{\partial x_i}$ be bounded in ${\mathrm{△}}_1$ and

Let

By assumption (H₁), if $x_i\le M$, there exists a constant $M_1>0$ such that $|\frac{\partial G}{\partial x_i}|\le M_1$. From (3.3) and (3.4), we get

Thus

i.e.,

We claim that there exists a point $t_1\in \mathbb{R}$ such that

In fact, for $\mathrm{\forall }t\in [0,T]$, we have $x_i(t-\gamma (t))>M$, and by (3.4), we have ${\int }_0^T\frac{\partial G(x(t-\gamma (t)))}{\partial x_i}dt>0$, which is a contradiction; see (3.3). So there must be a point $\xi \in [0,T]$ such that

Similar to the above proof, there must be a point $\eta \in [0,T]$ such that

1. (1)

   If $x_i(\xi -\gamma (\xi ))\ge -M$, by (3.7) we have

   $$\left|x_i(\xi -\lambda (\xi ))\right|\le M.$$

Let $t_1=\xi -\gamma (\xi )$. This proves (3.6).

1. (2)

   If $x_i(\xi -\gamma (\xi ))<-M$, from (3.8) and the fact that $x_i(t)$ is continuous on ℝ, there is a point $t_1$ between $\xi -\gamma (\xi )$ and $\eta -\gamma (\eta )$ such that $|x_i(t_1)|\le M$. This also proves (3.6). Let $t_1=k\pi +t_2$, $k\in \mathbb{Z}$, $t_2\in [0,T]$. Then $|x_i(t_1)|=|x_i(t_2)|\le M$. Hence we get

   $$\begin{array}{r}|x_i(t)|=\underset{t\in [0,T]}{max}|x_i(t_2)+{\int }_{t_2}^t{x}_i^{\prime }(s)ds|\le |x_i(t_2)|+{\int }_0^T|x_i^{\prime }(s)|ds\le M+{\int }_0^T|x^{\prime }(s)|ds,\\ {|x|}_0\le \sqrt{n}(M+{\int }_0^T|x^{\prime }(s)|ds)\le \sqrt{n}(M+T^{\frac{1}{2}}{\left({\int }_0^T{|x^{\prime }(s)|}^{2}ds\right)}^{\frac{1}{2}}).\end{array}$$

Multiplying the two sides of system (3.2) by $x^T(t)$ and integrating them over $[0,T]$, combining with $\tau =mT$, by (3.9) we have

i.e.,

From (3.9) and $({\lambda }_{2,i}Tn+n{\lambda }_{1,i}\sqrt{n})T+{\lambda }_{0,i}<1$, there is a constant $M_2>0$ such that

In view of (3.9) and (3.10), we get

From Lemma 2.2, ${(Ax(t))}^{″}=A{x}^{″}(t)-2C^{\prime }(t)x^{\prime }(t-\tau )-C^{″}(t)x(t-\tau )$ and (3.2), if ${\lambda }_{0,i}<\frac{1}{2}$, we have

From assumption (H₃) and (3.10)-(3.12), we get

So there exists a constant $M_4>0$ such that

Since $x(t)\in C_T^1$, ${\int }_0^T{x}^{\prime }(t)dt=0$, there is a constant vector $\alpha \in {\mathbb{R}}^n$ such that $x^{\prime }(\alpha )=0$; then by (3.13) we get

Thus

Step 2. Let $\mathrm{\Omega }\{x\in KerL:QNx=0\}$, we shall prove that ${\mathrm{\Omega }}_2$ is a bounded set. We have $x(t)=a_0\phi (t)$, $a_0\in \mathbb{R}$$\mathrm{\forall }x\in {\mathrm{\Omega }}_2$; then

When ${\lambda }_{0,i}<\frac{1}{2}$, $i\in I_n$, we have

Then we have

Thus

Otherwise, if, $\mathrm{\forall }t\in [0,T]$, $|a_0\phi (t)|>M$, then from assumption (H₂), we have

which is a contradiction; see (3.14). When ${\sigma }_{0,i}>1$, $i\in I_n$, we have

Then we have

Thus

Otherwise, if $\mathrm{\forall }t\in [0,T]$, $|a_0\phi (t)|>M$, then from assumption (H₂), we have

which is a contradiction; see (3.14). Hence ${\mathrm{\Omega }}_2$ is a bounded set.

Step 3. Let $\mathrm{\Omega }=\{x\in C_T^1:{|x|}_0<n{M}_2+1,{|x^{\prime }|}_0<n{M}_4+1\}$, then ${\mathrm{\Omega }}_1\cup {\mathrm{\Omega }}_2\subset \mathrm{\Omega }$, $\mathrm{\forall }(x,\lambda )\in \partial \mathrm{\Omega }\times (0,1)$, and from the above proof, $Lx\ne \lambda Nx$ is satisfied. Obviously, condition (2) of Lemma 2.3 is also satisfied. Now we prove that condition (3) of Lemma 2.3 is satisfied. We have $|x^0|={|a_0\phi |}_0$, $a_0\in \mathbb{R}$, $\mathrm{\forall }{x}^0\in \partial \mathrm{\Omega }\cap KerL$. There at least exists a $i\in I_n$ such that $|x_i^0|>M$. When $x_i^0>M$, take the homotopy

Then, by using assumption (H₂), we have $H(x,\mu )\ne 0$. When $x_i^0<-M$, take the homotopy

We also have $H(x,\mu )\ne 0$. Then by degree theory,

Applying Lemma 2.3, we reach the conclusion. □

Remark 3.1

When $\frac{1}{2}\le {\lambda }_{0,i}<1$ or ${\sigma }_{0,i}<1$, there are no existence results for periodic solutions for system (1.1). We hope that there is interest in doing further research on this issue.

As an application, we consider the following system:

where

Clearly, system (3.15) is a particular case of system (1.1). Obviously,

Here assumptions (H₁)-(H₂) are all satisfied. In addition,