Lazer-Leach type condition for second order differential equations at resonance with impulsive effects via variational method

In this paper, we study the existence of periodic solutions of second order impulsive differential equations at resonance with impulsive effects. We prove the existence of periodic solutions under a generalized Lazer-Leach type condition by using variational method. The impulses can generate a periodic solution.

We are concerned with the periodic boundary value problem of second order impulsive differential equations at resonance

where $m\in \mathbb{N}$, $g:\mathbb{R}\to \mathbb{R}$ is a continuous function, $e\in L^1(0,2\pi )$, $0<t_1<t_2<\cdots <t_p<2\pi$, and $I_j:[0,2\pi ]\times \mathbb{R}\to \mathbb{R}$ is continuous for every j.

When $\mathrm{\Delta }{x}^{\prime }(t_j)\equiv 0$, problem (1.1) becomes the well-known periodic boundary value problem at resonance

Assume that

exist and are finite. Lazer and Leach [1] proved that (1.2) has at least one 2π-periodic solution provided that the following condition holds:

From then on, a series of relevant resonant problems were studied (see [2]–[5] and the references cited therein) by some classical tools such as topological degree method, variational method, etc. Recently, the periodic problem of the second order differential equation with impulses has been widely studied because of its background in applied sciences (see [6]–[18] and the references cited therein). In this paper, we investigate problem (1.1) under a more general Lazer-Leach type condition. Define

and for $j=1,2,\dots ,p$,

Throughout this paper, we give the following fundamental assumptions.

(H₁): The limits

exist and are finite.

(H₂): There exist continuous, 2π-periodic functions $K_1(t),K_2(t),\dots ,K_p(t)$ such that for $j=1,2,\dots ,p$,

(H₃): For all $\theta \in \mathbb{R}$,

For the sake of convenience, we decompose (H₃) into the following two conditions.

(${\mathrm{H}}_3^{+}$): For all $\theta \in \mathbb{R}$,

(${\mathrm{H}}_3^{-}$): For all $\theta \in \mathbb{R}$,

We now can state the main theorems of this paper.

Theorem 1.1

Assume that conditions (H₁), (H₂) and (${\mathrm{H}}_3^{+}$) hold. Then problem (1.1) has at least one 2π-periodic solution.

Theorem 1.2

Assume that conditions (H₁), (H₂) and (${\mathrm{H}}_3^{-}$) hold. Then problem (1.1) has at least one 2π-periodic solution.

From Theorem 1.1 and Theorem 1.2, we obtain the following theorem.

Theorem 1.3

Assume that conditions (H₁), (H₂) and (H₃) hold. Then problem (1.1) has at least one 2π-periodic solution.

Moreover, we have the following corollary.

Corollary 1.4

Assume that conditions (H₁) and

(${\mathrm{H}}_3^{\prime }$): for all$\theta \in \mathbb{R}$,

hold. Then problem (1.2) has at least one 2π-periodic solution.

Remark 1.5

It is easy to find a function $g(x)$ such that (g) is not satisfied and (H₁) holds. For example, we can take $g(x)=cosx$. Hence, Corollary 1.4 improves the related results in the literature mentioned above. Moreover, since we consider the problem with impulses, Theorem 1.3 is also a complement of the pioneering works.

Remark 1.6

When condition (${\mathrm{H}}_3^{\prime }$) is not satisfied, i.e., there exists ${\theta }_0\in \mathbb{R}$ such that

problem (1.2) may have no solution. For example, we consider the resonant differential equation

Obviously, $g(x)=arctanx$, $e(t)=4cosmt$ and $G(+\mathrm{\infty })=\frac{\pi }{2}$, $G(-\mathrm{\infty })=-\frac{\pi }{2}$. We have

We take ${\theta }_0\in \mathbb{R}$ such that $sin{\theta }_0=\frac{1}{2}$. Then (${\mathrm{H}}_3^{\prime }$) is not satisfied. From now on, we prove that (1.5) has no 2π-periodic solution by contradiction. Assume that (1.5) has 2π-periodic solution. Multiplying both sides of (1.5) by $cosmt$ and integrating over $[0,2\pi ]$, we get

which is impossible. Hence, problem (1.2) may have no solution if condition (${\mathrm{H}}_3^{\prime }$) is not satisfied. Now, we give the following boundary value condition:

and the impulsive condition

Clearly, $p=1$ and $K_1(\frac{\pi }{m})=3\pi$. Then

Hence, (H₁), (H₂) and (H₃) hold. Equivalently, Eq. (1.5) with conditions (1.6) and (1.7) has at least one 2π-periodic solution. Therefore, the impulses in problem (1.1) can generate a periodic solution.

The rest of the paper is organized as follows. In Section 2, we shall state some notations, some necessary definitions and a saddle theorem due to Rabinowitz. In Section 3, we shall prove Theorem 1.1 and Theorem 1.2.

In the following, we introduce some notations and some necessary definitions.

Define

with the norm

Consider the functional $\phi (x)$ defined on H by

Similarly as in [18], $\phi (x)$ is continuously differentiable on H, and

Now, we have the following lemma.

Lemma 2.1

If$x\in H$is a critical point of φ, then x is a 2π-periodic solution of Eq. (1.1).

The proof of Lemma 2.1 is similar to Lemma 2.1 in [9], so we omit it.

We say that φ satisfies (PS) if every sequence $(x_n)$ for which $\phi (x_n)$ is bounded in ℝ and ${\phi }^{\prime }(x_n)\to 0$ (as $n\to \mathrm{\infty }$) possesses a convergent subsequence.

To prove the main result, we will use the following saddle point theorem due to Rabinowitz [19] (or see [20]).

Theorem 2.2

Let$\phi \in C^1(H,\mathbb{R})$and$H=H^{-}\oplus H^{+}$, $dim(H^{-})<\mathrm{\infty }$, $dim(H^{+})=\mathrm{\infty }$. We suppose that:

1. (a)

   there exist a bounded neighborhood D of 0 in $H^{-}$ and a constant α such that $\phi {|}_{\partial D}⩽\alpha$;

2. (b)

   there exists a constant $\beta >\alpha$ such that $\phi {|}_{H^{+}}⩾\beta$;

3. (c)

   φ satisfies (PS).

Then the functional φ has a critical point in H.

In this section, we first show that the functional φ satisfies the Palais-Smale condition.

Lemma 3.1

Assume that conditions (H₁), (H₂) and (H₃) hold. Then φ defined by (2.1) satisfies (PS).

Proof

Let $M>0$ be a constant and $\{x_n\}\subset H$ be a sequence satisfying

and

We first prove that $\{x_n\}$ is bounded in H by contradiction. Assume that $\{x_n\}$ is unbounded. Let $\{z_k\}$ be an arbitrary sequence bounded in H. It follows from (3.2) that, for any $k\in \mathbb{N}$,

Thus

Hence

By (H₁) and (H₂), we have

From (3.3) and (3.4), we obtain

Set

Then we have

and furthermore,

Replacing $z_k$ in (3.6) by $(y_n-y_i)$, we get

Due to the compact imbedding $H\hookrightarrow L^2(0,2\pi )$, going to a subsequence,

Therefore,

Furthermore, we have

which implies that $\{y_n\}$ is a Cauchy sequence in H. Thus, $y_n\to y_0$ in H. It follows from (3.5) and the usual regularity argument for ordinary differential equations (see [21]) that

where $k_1^2+k_2^2=\frac{1}{(m^2+1)\pi }$ ($\parallel y_0\parallel =1$). (Different subsequences of $\{y_n\}$ correspond to different $k_1$ and $k_2$.)

Write (3.7) as

where θ satisfies $sin\theta =\frac{k_2}{\sqrt{k_1^2+k_2^2}}$ and $cos\theta =\frac{k_1}{\sqrt{k_1^2+k_2^2}}$.

Taking $z_k=\frac{1}{\sqrt{(m^2+1)\pi }}sin(mt+\theta )$, we get, for any $n\in \mathbb{N}$,

Thus, it follows from (3.3) and (3.8) that

By (H₁) and (H₂), we obtain

It follows from (3.9) and (3.10) that

Hence, replacing $z_k$ in (3.3) by $y_n$, we have

Now, dividing (3.1) by $\parallel x_n\parallel$, we get

Passing to the limits, we have

Noting that $\frac{x_n}{\parallel x_n\parallel }\to \frac{1}{\sqrt{(m^2+1)\pi }}sin(mt+\theta )$ in H as $n\to \mathrm{\infty }$ and

where $I_{+}:=\{t\in [0,2\pi ]\mid sin(mt+\theta )>0\}$, $I_{-}:=\{t\in [0,2\pi ]\mid sin(mt+\theta )<0\}$, we get from the Lebesgue domain convergence theorem that

i.e.,

which contradicts (H₃). This implies that the sequence $\{x_n\}$ is bounded. Thus, there exists $x_0\in H$ such that $x_n\rightharpoonup x_0$ weakly in H. Due to the compact imbedding $H\hookrightarrow L^2(0,2\pi )$ and $H\hookrightarrow C(0,2\pi )$, going to a subsequence,

From (3.3), we obtain

Replacing $z_k$ by $x_n-x_i$ in the above equality, we get

By (H₁) and (H₂), we have

and

Thus, it follows from (3.12), (3.13) and (3.14) that

Therefore,

which implies $x_n\to x_0$ in H. It shows that φ satisfies (PS). □

Remark 3.2

If conditions (H₁), (H₂) and (${\mathrm{H}}_3^{+}$) (or (${\mathrm{H}}_3^{-}$)), φ defined by (2.1) still satisfies (PS).

Now, we can give the proof of Theorem 1.1.

Proof of Theorem 1.1

Denote

and

We first prove that

by contradiction. Assume that there exists a sequence $(x_n)\subset H^{-}$ such that $\parallel x_n\parallel \to \mathrm{\infty }$ (as $n\to \mathrm{\infty }$) and there exists a constant $c_{-}$ satisfying

By (H₁), we have

By (H₂), we get

From (3.16) and the definition of φ, we obtain

For $x\in H^{-}$, we get that there exist constants $a_0,a_1,\dots ,a_m$, $b_1,b_2,\dots ,b_m$ such that

Since ${\int }_0^{2\pi }{sin}^{2}jtdt={\int }_0^{2\pi }{cos}^{2}jtdt$ for $j=1,2,\dots$ , we have, for $x\in H^{-}$,

Hence, for $x\in H^{-}$,

The equality in (3.20) holds only for

Set $y_n=\frac{x_n}{\parallel x_n\parallel }$. Since $dim{H}^{-}<\mathrm{\infty }$, going to a subsequence, there exists $y_0\in H^{-}$ such that $y_n\to y_0$ in H and $y_n\to y_0$ in $L^2(0,2\pi )$. Then (3.17), (3.18), (3.19) and (3.20) imply that

By (3.16), we have, for n large enough,

It follows from $x_n\in H^{-}$ that

From (3.21) and (3.22), we get, for n large enough,

Passing to the limits and using an argument similarly as in the proof of Lemma 3.1, we get

which is a contradiction to (${\mathrm{H}}_3^{+}$).

Then (3.15) holds.

Next, we prove that

and φ is bounded on bounded sets.

Because of the compact imbedding of $H\hookrightarrow C(0,2\pi )$ and $H\hookrightarrow L^2(0,2\pi )$, there exist constants $m_1$, $m_2$ such that

Then by (H₁) and (H₂), one has that there exist positive constants $c_g,c_1,c_2,\dots ,c_p$ such that

Hence, φ is bounded on the bounded sets of H.

For $x\in H^{+}$, using an argument similar to the case $x\in H^{-}$, we have

Thus, from (3.23) and (3.24), we obtain

which implies

Up to now, the conditions (a) and (b) of Theorem 2.2 are satisfied. According to Remark 3.2, (c) is also satisfied. Hence, by Theorem 2.2, problem (1.1) has at least one solution. This completes the proof. □

Next, we prove Theorem 1.2 slightly differently from Theorem 1.1.

Proof of Theorem 1.2

Denote

and

We first prove that

For $x\in H^{-}$, we get that there exist constants $a_0,a_1,\dots ,a_{m-1}$, $b_1,b_2,\dots ,b_{m-1}$ such that

Since ${\int }_0^{2\pi }{sin}^{2}jtdt={\int }_0^{2\pi }{cos}^{2}jtdt$ for $j=1,2,\dots$ , we have, for $x\in H^{-}$,

Hence, for $x\in H^{-}$,

The equality holds only for

If $x\in H^{-}$ and $\parallel x\parallel \to \mathrm{\infty }$, then

For $x\in H^{-}$, we have

By (H₁) and (H₂), we get that there exists a constant $c_0>0$ such that

Hence, for $x\in H^{-}$, we obtain

Therefore, (3.25) holds.

Next, we prove that

and φ is bounded on bounded sets.

Because of the compact imbedding of $H\hookrightarrow C(0,2\pi )$ and $H\hookrightarrow L^2(0,2\pi )$, there exist constants $m_1$, $m_2$ such that

Then, by (H₁) and (H₂), one has that there exist positive constants $c_g,c_1,c_2,\dots ,c_p$ such that

Hence, φ is bounded on the bounded sets of H.

In what follows, we prove that

by contradiction. Assume that there exists a sequence $(x_n)\subset H^{-}$ such that $\parallel x_n\parallel \to \mathrm{\infty }$ (as $n\to \mathrm{\infty }$), and there exists a constant $c_{+}$ satisfying

By (H₁), we have

By (H₂), we get