Existence of solutions of a second-order impulsive differential equation

Abstract

This paper is concerned with the existence of solutions of a second-order impulsive differential equation with mixed boundary condition. We obtain sufficient conditions for the existence of a unique solution, at least one solution, at least two solutions and infinitely many solutions, respectively, by using critical point theorems. The main results are also demonstrated with examples.

MSC:34B15, 34B18, 34B37, 58E30.

1 Introduction

Nowadays, with the rapid development of science and technology, many people have realized that the theory of impulsive differential equations is not only richer than the corresponding theory of differential equations but it also represents a more natural framework for mathematical modeling of real world phenomena. Hence, it has become an effective tool to study some problems of biology, medicine, physics and so on [1, 2]. Significant progress has been made in the theory of systems of impulsive differential equations in recent twenty years (see [3–8] and the references cited therein). We generally consider impulses in the position u and $u^{\prime }$ for the second-order differential equation $u^{″}=f(t,u,u^{\prime })$. However, it is well known that in the motion of spacecraft instantaneous impulses depend on the position, which results in jump discontinuities in velocity, with no change in the position. This motivates us to consider the following second-order impulsive differential equation:

$$\{\begin{array}{c}-u^{″}(t)+g(t)u(t)=f(t,u(t)),t\ne t_j,t\in J=[0,T],T>0,\hfill \\ -\mathrm{\Delta }{u}^{\prime }(t_j)=I_j(u(t_j)),j=1,2,\dots ,m,\hfill \\ u(0)=0,\alpha u(T)+\beta u^{\prime }(T)=0,\hfill \end{array}$$

(1.1)

where $f\in C(J\times R,R)$, $g\in L^{\mathrm{\infty }}[0,T]$, $g(t)>0$, $I_j\in C(R,R)$, $0=t_0<t_1<t_2<\cdots <t_m<t_{m+1}=T$, α, β are constants with $\alpha \ge 0$, $\beta >0$, and the operator Δ is defined as $\mathrm{\Delta }{u}^{\prime }(t_j)=u^{\prime }(t_j^{+})-u^{\prime }(t_j^{-})$, where $u^{\prime }(t_j^{+})(u^{\prime }(t_j^{-}))$ denotes the right-hand (left-hand) limit of $u^{\prime }$ at $t_j$.

In recent years, some classical tools such as some fixed point theorems in cones, topological degree theory and the upper and lower solutions method combined with the monotone iterative technique [9–14] have been widely used to get solutions of impulsive differential equations. On the other hand, in the last few years, some researchers have studied the existence of solutions for impulsive differential equations with boundary conditions via variational methods [15–19]. In this paper, we consider (1.1) by using critical point theory and variational methods.

The rest of this paper is organized as follows. In Section 2 we present several important lemmas. In Section 3, we present existence results of equation (1.1) by using critical point theory and variational methods.

2 Preliminaries

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

Definition 2.1 [20]

Let X be a real reflexive Banach space. For any sequence $\{u_k\}\subset X$, if $\{\phi (u_k)\}$ is bounded and ${\phi }^{\prime }(u_k)\to 0$ as $k\to \mathrm{\infty }$ possesses a convergent subsequence, then we say that φ satisfies the Palais-Smale condition (PS condition).

Definition 2.2 [20]

Let $\phi :X\to R$ be differentiable and $c\in R$. We say that φ satisfies the ${\text{(PS)}}_c$ condition if the existence of a sequence $\{u_k\}$ in X, such that $\phi (u_k)\to c$, ${\phi }^{\prime }(u_k)\to 0$ as $k\to \mathrm{\infty }$, implies that c is a critical value of φ.

It is clear that the PS condition implies the ${\text{(PS)}}_c$ condition for each $c\in R$.

Lemma 2.3 [21]

Let H be a Hilbert space and $a:H\times H\to R$ be a bounded bilinear form. If a is coercive, i.e., there exists $\alpha >0$ such that $a(u;u)\ge \alpha {\parallel u\parallel }^2$ for every $u\in H$, then for any $\sigma \in H^{\prime }$ (the conjugate space of H), there exists a unique $u\in H$ such that

$$a(u,v)=(\sigma ,v)\mathit{\text{for every}}v\in H.$$

Moreover, if a is also symmetric, then the functional $\phi :H\to R$ defined by $\phi =\frac{1}{2}a(v,v)-(\sigma ,v)$ attains its minimum at u.

Lemma 2.4 [20]

If φ is weakly lower semi-continuous on a reflexive Banach space X and has a bounded minimizing sequence, then φ has a minimum on X. The existence of a bounded minimizing sequence will be in particular insured when φ is coercive, i.e., such that $\phi (u)\to +\mathrm{\infty }$ if $\parallel u\parallel \to \mathrm{\infty }$.

Lemma 2.5 [22]

For the functional $F:M\subseteq X\to R$ with M not empty, ${min}_{u\in M}F(u)=a$ has a solution in case the following hold:

1. (i)

   X is a real reflexive Banach space;

2. (ii)

   M is bounded and weakly sequentially closed;

3. (iii)

   F is weakly sequentially lower semi-continuous on M, i.e., by definition, for each sequence $\{u_k\}$ in M such that $u_k\rightharpoonup u$ as $k\to \mathrm{\infty }$, we have $F(u)\le {\underline{lim}}_{k\to \mathrm{\infty }}F(u_k)$.

Lemma 2.6 [20]

Let X be a Banach space and $\phi \in C^1(X,R)$. Assume that there exist $u_0\in X$, $u_1\in X$ and a bounded open neighborhood Ω of $u_0$ such that $u_1\in X\setminus \mathrm{\Omega }$ and

$$\underset{\partial \mathrm{\Omega }}{inf}\phi >max\{\phi (u_0),\phi (u_1)\}.$$

Let

$$\mathrm{\Gamma }=\{h\in C([0,1],X):h(0)=u_0,h(1)=u_1\}$$

and

$$c=\underset{h\in \mathrm{\Gamma }}{inf}\underset{s\in [0,1]}{max}\phi (h(s)).$$

If φ satisfies the ${\text{(PS)}}_c$, then c is a critical value of φ and $c>max\{\phi (u_0),\phi (u_1)\}$.

Lemma 2.7 [23]

Let X be an infinite dimensional Banach space and let $\phi \in C^1(X,R)$ be even, satisfying the (PS), and $\phi (0)=0$. If $X=V\oplus W$, where V is finite dimensional, and φ satisfies the following conditions:

1. (i)

   There exist constants $\rho ,\sigma >0$ such that $\phi {|}_{\partial B_{\rho }\cap W}\ge \sigma$;

2. (ii)

   For each finite dimensional subspace $V_1\subset X$, there is an $R=R(V_1)$ such that $\phi (u)\le 0$ for every $u\in V_1$ with $\parallel u\parallel >R$;

then φ possesses an unbounded sequence of critical values.

Let

$$H^1([0,T])=\{u\in L^2([0,T]):u^{\prime }\in L^2([0,T])\}$$

and

$$H^2([0,T])=\{u\in L^2([0,T]):u^{\prime },u^{″}\in L^2([0,T])\}.$$

Take $H=\{u\in H^1([0,T]):u(0)=0\}$. Then H is a Hilbert space, and the inner product

$$(u,v)={\int }_0^T{u}^{\prime }(t)v^{\prime }(t)dt+{\int }_0^{T}g(t)u(t)v(t)dt$$

induces the norm

$$\parallel u\parallel ={({\int }_0^T{(u^{\prime }(t))}^{2}dt+{\int }_0^{T}g(t)u^2(t)dt)}^{\frac{1}{2}}.$$

For $u\in H^2([0,T])$, we have that u and $u^{\prime }$ are both absolutely continuous and $u^{″}\in L^2([0,T])$, hence $\mathrm{\Delta }{u}^{\prime }(t_j)=u^{\prime }(t_j^{+})-u^{\prime }(t_j^{-})=0$ for any $t\in J$. If $u\in H$, then u is absolutely continuous and $u^{\prime }\in L^2([0,T])$. In this case, the one-side derivatives $u^{\prime }(t_j^{+})$ and $u^{\prime }(t_j^{-})$ may not exist. So, by a classical solution of (1.1), we mean a function $u\in C([0,T])$ satisfying the following conditions: For every $j=0,1,\dots ,m$, $u_j=u{|}_{(t_j,t_{j+1})}\in H^2(t_j,t_{j+1})$; u satisfies the boundary condition of (1.1) and the first equation of (1.1); $u^{\prime }(t_j^{+})$ and $u^{\prime }(t_j^{-})$, $j=0,1,\dots ,m$, exist and the impulsive conditions of (1.1) hold.

Taking $v\in H$ and multiplying (1.1) by v and integrating from 0 to T, we have

$$-{\int }_0^T{u}^{″}(t)v(t)dt+{\int }_0^{T}g(t)u(t)v(t)dt={\int }_0^{T}f(t,u(t))v(t)dt.$$

This leads to

$$\begin{array}{r}{\int }_0^T{u}^{\prime }(t)v^{\prime }(t)dt+{\int }_0^{T}g(t)u(t)v(t)dt-\sum _{j=1}^m{I}_j(u(t_j))v(t_j)+\frac{\alpha }{\beta }u(T)v(T)\\ ={\int }_0^{T}f(t,u(t))v(t)dt.\end{array}$$

(2.1)

Thus, a weak solution of (1.1) is a function $u\in H$ such that (2.1) holds for any $v\in H$. By the regularity theory, the weak solution is a classical solution. Now, we define $\phi :H\to R$ by

$$\begin{array}{rl}\phi (u)=& \frac{1}{2}{\int }_0^T[{(u^{\prime }(t))}^2+g(t)u^2(t)]dt-{\int }_0^{T}F(t,u(t))dt-\sum _{j=1}^m{\int }_0^{u(t_j)}{I}_j(t)dt\\ +\frac{\alpha }{2\beta }{u}^2(T),\end{array}$$

(2.2)

where $F(t,u(t))={\int }_0^{u}f(t,s)ds$. Clearly, φ is Fréchet differentiable at any $u\in H$ and

$$\begin{array}{rl}{\phi }^{\prime }(u)(v)=& \underset{h\to 0}{lim}\frac{\phi (u+hv)-\phi (u)}{h}\\ =& {\int }_0^T[u^{\prime }(t)v^{\prime }(t)+g(t)u(t)v(t)]dt-{\int }_0^{T}f(t,u(t))v(t)dt\\ -\sum _{j=1}^m{I}_j(u(t_j))v(t_j)+\frac{\alpha }{\beta }u(T)v(T)\end{array}$$

(2.3)

for any $v\in H$. Obviously, ${\phi }^{\prime }$ is continuous, and a critical point of φ gives a weak solution of (1.1).

Lemma 2.8 If the function $u\in H$ is a critical point of the functional φ, then u is a solution of system (1.1).

Proof Suppose that $u\in H$ is a critical point of the functional φ. Then, for any $v\in H$, one has

$${\phi }^{\prime }(u)(v)=0.$$

(2.4)

From (2.3), one has

$$\begin{array}{r}{\int }_0^T[u^{\prime }(t)v^{\prime }(t)+g(t)u(t)v(t)]dt-{\int }_0^{T}f(t,u(t))v(t)dt-\sum _{j=1}^m{I}_j(u(t_j))v(t_j)+\frac{\alpha }{\beta }u(T)v(T)\\ =-\sum _{j=1}^m(\mathrm{\Delta }{u}^{\prime }(t_j)+I_j(u(t_j)))v(t_j)+{\int }_0^T(-u^{″}(t)+g(t)u(t))v(t)dt\\ -{\int }_0^{T}f(t,u(t))v(t)dt+(u^{\prime }(T)+\frac{\alpha }{\beta }u(T))v(T).\end{array}$$

(2.5)

Combining (2.4) and (2.5), one has

$$\begin{array}{r}-\sum _{j=1}^m(\mathrm{\Delta }{u}^{\prime }(t_j)+I_j(u(t_j)))v(t_j)+{\int }_0^T(-u^{″}(t)+g(t)u(t))v(t)dt\\ -{\int }_0^{T}f(t,u(t))v(t)dt+(u^{\prime }(T)+\frac{\alpha }{\beta }u(T))v(T)=0,\mathrm{\forall }v\in H.\end{array}$$

(2.6)

For $j\in \{1,2,\dots ,m\}$, we choose $v\in H$ with $v(t)=0$ for every $t\in [0,t_j]\cup [t_{j+1},T]$, then

$${\int }_{t_j}^{t_{j+1}}(-u^{″}(t)+g(t)u(t)-f(t,u(t)))v(t)dt=0.$$

We get

$$-u^{″}(t)+g(t)u(t)=f(t,u(t))\text{a.e. }t\in (t_j,t_{j+1}).$$

Thus, u satisfies the equation in (1.1).

Therefore, by (2.6) we have

$$-\sum _{j=1}^m(\mathrm{\Delta }{u}^{\prime }(t_j)+I_j(u(t_j)))v(t_j)+(u^{\prime }(T)+\frac{\alpha }{\beta }u(T))v(T)=0,\mathrm{\forall }v\in H.$$

(2.7)

Next we prove that u satisfies the impulsive and the boundary condition in (1.1). If the impulsive condition in (1.1) does not hold, then there exist some $j\in \{1,2,\dots ,m\}$ such that

$$\mathrm{\Delta }{u}^{\prime }(t_j)+I_j(u(t_j))\ne 0.$$

(2.8)

Pick $v(t)={\prod }_{i=0,i\ne j}^{m+1}(t-t_i)$, then

$$\begin{array}{r}-\sum _{j=1}^m(\mathrm{\Delta }{u}^{\prime }(t_j)+I_j(u(t_j)))v(t_j)+(u^{\prime }(T)+\frac{\alpha }{\beta }u(T))v(T)\\ =-\sum _{j=1}^m(\mathrm{\Delta }{u}^{\prime }(t_j)+I_j(u(t_j)))\prod _{i=0,i\ne j}^{m+1}(t_j-t_i)+(u^{\prime }(T)+\frac{\alpha }{\beta }u(T))\prod _{i=0,i\ne j}^{m+1}(t_{m+1}-t_i)\\ =-(\mathrm{\Delta }{u}^{\prime }(t_j)+I_j(u(t_j)))\prod _{i=0,i\ne j}^{m+1}(t_j-t_i)\ne 0.\end{array}$$

(2.9)

This is a contradiction. So u satisfies the impulsive condition in (1.1) and (2.7) implies

$$(u^{\prime }(T)+\frac{\alpha }{\beta }u(T))v(T)=0,\mathrm{\forall }v\in H.$$

(2.10)

If $\alpha u(T)+\beta u^{\prime }(T)\ne 0$, then $\frac{\alpha }{\beta }u(T)+u^{\prime }(T)\ne 0$.

Pick $v(t)={\prod }_{i=0}^m(t-t_i)$. One has

$$(u^{\prime }(T)+\frac{\alpha }{\beta }u(T))\prod _{i=0}^m(t_{m+1}-t_i)\ne 0.$$

(2.11)

This contradicts (2.10), so u satisfies the boundary condition. Therefore, u is a solution of system (1.1). □

Lemma 2.9 If $u\in H$, then ${\parallel u\parallel }_{\mathrm{\infty }}\le T^{\frac{1}{2}}\parallel u\parallel$, where ${\parallel u\parallel }_{\mathrm{\infty }}={max}_{t\in [0,T]}|u(t)|$.

Proof The proof follows easily from the Hölder inequality. The detailed argument is similar to the proof of Lemma 2.2 in [24], and we thus omit it here. □

3 Main results

3.1 Existence of a unique solution

In this section we derive conditions under which system (1.1) admits a unique solution.

Theorem 3.1 Assume that $d_j$ ($j=1,2,\dots ,m$) are fixed constants, $f(t,u)=\sigma (t)\in L^2(0,T)$ and $I_j(t)=d_j$ ($j=1,2,\dots ,m$), then system (1.1) has a unique solution u, and u minimizes the functional (2.2).

Proof We define the bilinear form

$$a:H\times H\to R,a(u,v)={\int }_0^T(u^{\prime }(t)v^{\prime }(t)+g(t)u(t)v(t))dt+\frac{\alpha }{\beta }u(T)v(T)$$

and the linear operator

$$l:H\to R,l(v)={\int }_0^T\sigma (t)v(t)dt-\sum _{j=1}^m{d}_{j}v(t_j).$$

It is evident that a is continuous and symmetric and l is bounded. Moreover, a is coercive. By Lemma 2.3, system (1.1) has a unique solution u, and u minimizes the functional (2.2). □

Example 3.1 Consider the following boundary value problem:

$$\{\begin{array}{c}-u^{″}(t)+u(t)=0,t\ne t_1,t\in J=[0,1],\hfill \\ -\mathrm{\Delta }{u}^{\prime }(t_1)=1,t_1=\frac{1}{2},\hfill \\ u(0)=0,u(1)+u^{\prime }(1)=0.\hfill \end{array}$$

(3.1)

Here $g(t)=1$, $f(t,u)=0$, $I_j(u)=1$, $T=1$, $j=1$, $\alpha =1$, $\beta =1$. Applying Theorem 3.1, problem (3.1) has a unique solution. By simple calculations, we obtain $u(t)=\frac{1}{2}{e}^{-\frac{1}{2}}(e^t-e^{-t})$, $t\in [0,\frac{1}{2}]$, $u(t)=\frac{1}{2}(e^{\frac{1}{2}}-e^{-\frac{1}{2}})e^{-t}$, $t\in [\frac{1}{2},1]$.

3.2 Existence of at least one solution

In this section we derive conditions under which system (1.1) admits at least one solution. For this purpose, we introduce the following assumption.

(H1) There exist $a,b,a_j,b_j>0$, $\gamma ,{\gamma }_j\in [0,1)$, $j=1,2,\dots ,m$, such that

$$|f(t,u)|\le a+b{|u|}^{\gamma },|I_j(u)|\le a_j+b_j{|u|}^{{\gamma }_j}$$

for $t\in J$.

Theorem 3.2 Assume that (H1) is satisfied, then system (1.1) has at least one solution u, and u minimizes the functional (2.2).

Proof According to (H1), we have

$$\begin{array}{rl}\phi (u)=& \frac{1}{2}{\parallel u\parallel }^2-{\int }_0^{T}F(t,u(t))dt-\sum _{j=1}^m{\int }_0^{u(t_j)}{I}_j(t)dt+\frac{\alpha }{2\beta }{u}^2(T)\\ \ge & \frac{1}{2}{\parallel u\parallel }^2-T(a{\parallel u\parallel }_{\mathrm{\infty }}+\frac{b}{\gamma +1}{\parallel u\parallel }_{\mathrm{\infty }}^{\gamma +1})-\sum _{j=1}^m(a_j{\parallel u\parallel }_{\mathrm{\infty }}+\frac{b_j}{{\gamma }_j+1}{\parallel u\parallel }_{\mathrm{\infty }}^{{\gamma }_j+1})\\ \ge & \frac{1}{2}{\parallel u\parallel }^2-T(a{T}^{\frac{1}{2}}\parallel u\parallel +\frac{b}{\gamma +1}{T}^{\frac{\gamma +1}{2}}{\parallel u\parallel }^{\gamma +1})\\ -\sum _{j=1}^m(a_j{T}^{\frac{1}{2}}\parallel u\parallel +\frac{b_j}{{\gamma }_j+1}{T}^{\frac{{\gamma }_j+1}{2}}{\parallel u\parallel }^{{\gamma }_j+1})\end{array}$$

for all $u\in H$. This implies that φ is coercive.

Let $\{u_n\}$ be a weakly convergent sequence to u in H, then $\{u_n\}$ converges uniformly to u in $C[0,T]$.

Set

$$\begin{array}{r}{\phi }_1(u)=-{\int }_0^{T}F(t,u(t))dt-\sum _{j=1}^m{\int }_0^{u(t_j)}{I}_j(t)dt+\frac{\alpha }{2\beta }{u}^2(T),\\ {\phi }_2(u)=\frac{1}{2}{\int }_0^T[{(u^{\prime }(t))}^2+g(t)u^2(t)]dt,\end{array}$$

then $\phi (u)={\phi }_1(u)+{\phi }_2(u)$. So ${\phi }_1$ is weakly sequentially continuous. Clearly, ${\phi }_2$ is continuous and convex, which implies that ${\phi }_2$ is weakly sequentially lower semi-continuous. Therefore, φ is weakly sequentially lower semi-continuous on H.

By Lemma 2.4, the functional φ has a minimum which is a critical point of φ. Hence, system (1.1) has at least one solution. □

Example 3.2 Consider the following boundary value problem:

$$\{\begin{array}{c}-u^{″}(t)+u(t)=1+u{(t)}^{\frac{1}{3}},t\ne t_1,t\in J=[0,1],\hfill \\ -\mathrm{\Delta }{u}^{\prime }(t_1)=1+u{(t)}^{\frac{1}{5}},t_1=\frac{1}{2},\hfill \\ u(0)=0,u(1)+u^{\prime }(1)=0.\hfill \end{array}$$

(3.2)

Here $g(t)=1$, $f(t,u)=1+u{(t)}^{\frac{1}{3}}$, $I_j(u)=1+u{(t)}^{\frac{1}{5}}$, $T=1$, $j=1$, $\alpha =1$, $\beta =1$. Clearly, (H1) is satisfied. Applying Theorem 3.2, problem (3.2) has at least one solution.

3.3 Existence of at least two distinct solutions

In this section, we derive some sufficient conditions under which the functional φ admits at least two distinct critical points; consequently, (1.1) admits at least two distinct solutions. We first introduce some assumptions.

(H2) ${lim}_{u\to 0}\frac{f(t,u)}{u}=0$ uniformly for $t\in J$, ${lim}_{u\to 0}\frac{I_j(u)}{u}=0$.

(H3) There exist constants $\mu >2$ and $r\ge 0$ such that for every $t\in J$ and $u\in R$ with $|u|\ge r$,

$$0<\mu F(t,u)\le uf(t,u),0<\mu {\int }_0^u{I}_j(s)ds\le u{I}_j(u),j=1,2,\dots ,m,$$

where $F(t,u)={\int }_0^{u}f(t,s)ds$.

Theorem 3.3 Assume that (H2) and (H3) are satisfied. Then system (1.1) has at least two solutions.

Proof The proof will be given in three steps.

Step 1. The functional φ satisfies the PS condition.

Let $\{u_n\}\subset H$ such that $\{\phi (u_n)\}$ is a bounded sequence and ${lim}_{n\to \mathrm{\infty }}{\phi }^{\prime }(u_n)=0$. We compute

$$\begin{array}{rl}\phi (u_n)-\frac{1}{\mu }{\phi }^{\prime }(u_n)(u_n)=& (\frac{1}{2}-\frac{1}{\mu }){\parallel u_n\parallel }^2+(\frac{1}{2}-\frac{1}{\mu })\frac{\alpha }{\beta }{u}_n^2(T)\\ -\sum _{j=1}^m{\int }_0^{u(t_j)}{I}_j(s)ds+\frac{1}{\mu }\sum _{j=1}^m{I}_j(u_n(t_j))u_n(t_j)\\ -{\int }_0^{T}F(t,u_n(t))dt+\frac{1}{\mu }{\int }_0^{T}f(t,u_n(t))u_n(t)dt\\ \ge & (\frac{1}{2}-\frac{1}{\mu }){\parallel u_n\parallel }^2+\sum _{j=1}^m(\frac{1}{\mu }{I}_j(u_n(t_j))u_n(t_j)-{\int }_0^{u(t_j)}{I}_j(s)ds)\\ +{\int }_0^T(\frac{1}{\mu }f(t,u_n(t))u_n(t)-F(t,u_n(t)))dt.\end{array}$$

(3.3)

By (H3), one has

$$\begin{array}{r}\phi (u_n)-\frac{1}{\mu }{\phi }^{\prime }(u_n)(u_n)\\ \ge (\frac{1}{2}-\frac{1}{\mu }){\parallel u_n\parallel }^2-\sum _{j=1}^m\underset{u_n(t)\in [-r,r]}{max}|\frac{1}{\mu }{I}_j(u_n(t_j))u_n(t_j)-{\int }_0^{u(t_j)}{I}_j(s)ds|\\ -{\int }_0^T\underset{t\in J,u_n(t)\in [-r,r]}{max}|\frac{1}{\mu }f(t,u_n(t))u_n(t)-F(t,u_n(t))|dt.\end{array}$$

(3.4)

Hence, $\{u_n\}$ is bounded in H.

From the reflexivity of H, we may extract a weakly convergent subsequence; for simplicity, we also note again by $\{u_n\}$, $u_n\rightharpoonup u$ in H. Next we prove that $\{u_n\}$ strongly converges to u in H. By (2.3) we have

$$\begin{array}{r}({\phi }^{\prime }(u_n)-{\phi }^{\prime }(u))(u_n-u)\\ ={\parallel u_n-u\parallel }^2+\frac{\alpha }{\beta }{(u_n(T)-u(T))}^2\\ -\sum _{j=1}^m(I_j(u_n(t_j))-I_j(u(t_j)))(u_n(t_j)-u(t_j))\\ -{\int }_0^T(f(t,u_n(t))-f(t,u(t)))(u_n(t)-u(t))dt.\end{array}$$

(3.5)

$u_n\rightharpoonup u$ in H implies that $\{u_n\}$ uniformly converges to u in $C[0,T]$. So

$$\begin{array}{r}\sum _{j=1}^m(I_j(u_n(t_j))-I_j(u(t_j)))(u_n(t_j)-u(t_j))\to 0,\\ {\int }_0^T(f(t,u_n(t))-f(t,u(t)))(u_n(t)-u(t))dt\to 0,\\ u_n(T)-u(T)\to 0\text{as }n\to \mathrm{\infty }.\end{array}$$

(3.6)

By ${\phi }^{\prime }(u_n)\to 0$ and $u_n\rightharpoonup u$ as $n\to +\mathrm{\infty }$, we have

$$({\phi }^{\prime }(u_n)-{\phi }^{\prime }(u))(u_n-u)\to 0\text{as }n\to \mathrm{\infty }.$$

(3.7)

So (3.5), (3.6) and (3.7) yield $\parallel u_n-u\parallel \to 0$ in H, i.e., $\{u_n\}$ strongly converges to u in H. Therefore, the functional φ satisfies the PS condition.

Step 2. We show that there exists $\rho >0$ such that the functional φ has a local minimum $u_0\in B_{\rho }=\{u\in H:\parallel u\parallel <\rho \}$.

Firstly, we claim that $\overline{B_{\rho }}$ is bounded and weakly sequentially closed.

In fact, let $\{u_n\}\subseteq \overline{B_{\rho }}$ and $\{u_n\}\rightharpoonup u$ as $n\to \mathrm{\infty }$. By the Mazur theorem [22], there exists a sequence of convex combinations

$$v_n=\sum _{j=1}^n{\alpha }_{n_j}{u}_j,\sum _{j=1}^n{\alpha }_{n_j}=1,{\alpha }_{n_j}\ge 0,j\in N$$

such that $v_n\to u$ in H. $\{v_n\}\subset \overline{B_{\rho }}$ and $u\in \overline{B_{\rho }}$, since $\overline{B_{\rho }}$ is a closed convex set.

Secondly, we claim that the functional φ is weakly sequentially lower semi-continuous on $\overline{B_{\rho }}$.

Let

$$\begin{array}{r}{\phi }_1(u)=-{\int }_0^{T}F(t,u(t))dt-\sum _{j=1}^m{\int }_0^{u(t_j)}{I}_j(t)dt+\frac{\alpha }{2\beta }{u}^2(T),\\ {\phi }_2(u)=\frac{1}{2}{\int }_0^T[{(u^{\prime }(t))}^2+g(t)u^2(t)]dt,\end{array}$$

then $\phi (u)={\phi }_1(u)+{\phi }_2(u)$. By $\{u_n\}\rightharpoonup u$ on H, we see that $\{u_n\}$ uniformly converges to u in $C[0,T]$. So ${\phi }_1$ is weakly sequentially continuous. Clearly, ${\phi }_2$ is continuous and convex, which implies that ${\phi }_2$ is weakly sequentially lower semi-continuous. Therefore, φ is weakly sequentially lower semi-continuous on $\overline{B_{\rho }}$.

Thirdly, we claim that φ has a minimum $u_0\in \overline{B_{\rho }}$.

In fact, H is a reflexive Banach space, $\overline{B_{\rho }}$ is bounded and weakly sequentially closed and φ is weakly sequentially lower semi-continuous on $\overline{B_{\rho }}$. So, by Lemma 2.4, there exists $u_0\in \overline{B_{\rho }}$ such that $\phi (u_0)=min\{\phi (u):u\in \overline{B_{\rho }}\}$.

Finally, we claim that $\phi (u_0)<{inf}_{u\in \partial B_{\rho }}\phi (u)$.

By (H2), let $\epsilon =\frac{1}{3m{T}^2}>0$, there exists $\delta >0$ such that $|u|<\delta$ implies

$$|F(t,u)|\le \frac{\epsilon }{2}{|u|}^2,{\int }_0^u{I}_j(t)dt\le \frac{\epsilon }{2}{|u|}^2\text{for }t\in J.$$

(3.8)

Consequently, by Lemma 2.9, for $\parallel u\parallel \le \frac{\delta }{\sqrt{T}}$, we have

$$\begin{array}{rl}\phi (u)& =\frac{1}{2}{\parallel u\parallel }^2-{\int }_0^{T}F(t,u(t))dt-\sum _{j=1}^m{\int }_0^{u(t_j)}{I}_j(t)dt+\frac{\alpha }{2\beta }{u}^2(T)\\ \ge \frac{1}{2}{\parallel u\parallel }^2-{\int }_0^T\frac{\epsilon }{2}{|u(t)|}^{2}dt-\sum _{j=1}^m\frac{\epsilon }{2}{|u(t_j)|}^2+\frac{\alpha }{2\beta }{u}^2(T)\\ \ge \frac{1}{2}{\parallel u\parallel }^2-\frac{\epsilon T^2}{2}{\parallel u\parallel }^2-\frac{\epsilon m{T}^2}{2}{\parallel u\parallel }^2\\ \ge \frac{1}{2}{\parallel u\parallel }^2-\frac{1}{6}{\parallel u\parallel }^2-\frac{1}{6}{\parallel u\parallel }^2\\ \ge \frac{1}{6}{\parallel u\parallel }^2.\end{array}$$

Choose $C=\frac{{\delta }^2}{6T}$, $\rho =\frac{\delta }{\sqrt{T}}$, then $\phi (u)\ge C>0$ for any $u\in \partial B_{\rho }$. Besides, $\phi (u_0)\le \phi (0)=0<C\le \phi (u)$ for any $u\in \partial B_{\rho }$. So $\phi (u_0)<{inf}_{u\in \partial B_{\rho }}\phi (u)$. Hence, φ has a local minimum $u_0\in B_{\rho }=\{u\in H:\parallel u\parallel <\rho \}$.

Step 3. We prove that there exists $u_1$ with $\parallel u_1\parallel >\rho$ such that $\phi (u_1)<{inf}_{u\in \partial B_{\rho }}\phi (u)$.

Condition (H3) implies that there exist $b_1,b_2,c_j,d_j>0$, $j=1,2,\dots ,m$, such that

$$F(t,u)\ge b_1{|u|}^{\mu }-b_2,{\int }_0^u{I}_j(t)dt\ge c_j{|u|}^{\mu }-d_j$$

(3.9)

for $t\in J$, $u\in R$ (see [16]). Then we have

$$\begin{array}{rl}\phi (u)& =\frac{1}{2}{\parallel u\parallel }^2-{\int }_0^{T}F(t,u(t))dt-\sum _{j=1}^m{\int }_0^{u(t_j)}{I}_j(t)dt+\frac{\alpha }{2\beta }{u}^2(T)\\ \le \frac{1}{2}{\parallel u\parallel }^2-(b_1{T}^{\frac{\mu }{2}}{\parallel u\parallel }^{\mu }-b_2)T-\sum _{j=1}^m(c_j{T}^{\frac{\mu }{2}}{\parallel T\parallel }^{\mu }-d_j)+\frac{\alpha }{2\beta }{u}^2(T).\end{array}$$

(3.10)

Since $\mu >2$, (3.10) implies ${lim}_{\parallel u\parallel \to \mathrm{\infty }}\phi (u)=-\mathrm{\infty }$. Therefore, we can choose $u_1$ with $\parallel u_1\parallel >\rho$ sufficiently large such that $\phi (u_1)<{inf}_{u\in \partial B_{\rho }}\phi (u)$.

Let

$$c=\underset{h\in \mathrm{\Gamma }}{inf}\underset{t\in [0,1]}{max}\phi (h(t)),$$

where

$$\mathrm{\Gamma }=\{h\in C([0,1],H):h(0)=u_0,h(1)=u_1\}.$$

By Lemma 2.6, c is a critical value of φ, that is, there exists a critical point $u^{\ast }$. Therefore, $u_0$, $u^{\ast }$ are two critical points of φ, and they are solutions of (1.1). □

Example 3.3 Consider the following boundary value problem:

$$\{\begin{array}{c}-u^{″}(t)+u(t)=\frac{1}{15}{(u(t))}^{\frac{8}{3}}sint,t\ne t_j,t\in J=[0,1],\hfill \\ -\mathrm{\Delta }{u}^{\prime }(t_j)=\frac{1}{2}{u}^3(t_j),j=1,\hfill \\ u(0)=0,u(1)+u^{\prime }(1)=0.\hfill \end{array}$$

(3.11)

Here $g(t)=1$, $f(t,u)=\frac{1}{15}{(u(t))}^{\frac{8}{3}}sint$, $I_j(u)=\frac{1}{2}{u}^3$, $T=1$, $j=1$, $\alpha =1$, $\beta =1$. Let $\mu =3$, $r=1$. Clearly, (H2) and (H3) are satisfied. By Theorem 3.3, problem (3.11) has at least two solutions.

3.4 Existence of infinitely many solutions

In this section, we derive some conditions under which system (1.1) admits infinitely many distinct solutions. To this end, we need the following assumption.

(H4) $f(t,u)$ and $I_j$, $j=1,2,\dots ,m$, are odd about u.

Theorem 3.4 Assume that (H2), (H3) and (H4) are satisfied. Then system (1.1) has infinitely many solutions.

Proof We apply Lemma 2.7 to finish the proof. Clearly, $\phi \in C^1(H,R)$ is even since $f(t,u)$ and $I_j(u)$ are odd about u, and $\phi (0)=0$. The arguments of Theorem 3.3 show that the functional φ satisfies the PS condition. In the same way as in Theorem 3.3, we can easily verify that conditions (i) and (ii) of Lemma 2.7 are satisfied. According to Lemma 2.7, φ possesses infinitely many critical points, i.e., system (1.1) has infinitely many solutions. □

Example 3.4 Consider the following boundary value problem:

$$\{\begin{array}{c}-u^{″}(t)+u(t)=t{u}^3(t),t\ne t_j,t\in J=[0,1],\hfill \\ -\mathrm{\Delta }{u}^{\prime }(t_j)=\frac{1}{2}{u}^3(t_j),j=1,\hfill \\ u(0)=0,u(1)+u^{\prime }(1)=0.\hfill \end{array}$$

(3.12)

Here $g(t)=1$, $f(t,u)=t{u}^3$, $I_j(u)=\frac{1}{2}{u}^3$, $T=1$, $j=1$, $\alpha =1$, $\beta =1$. Obviously, $f(t,u)$, $I_j(u)$ are odd about u. Let $\mu =3$, $r=1$. Clearly, (H2) and (H3) are satisfied. Applying Theorem 3.4, problem (3.12) has infinitely many solutions.