Existence of two positive solutions for a class of third-order impulsive singular integro-differential equations on the half-line in Banach spaces

In this paper, we discuss the existence of two positive solutions for an infinite boundary value problem of third-order impulsive singular integro-differential equations on the half-line in Banach spaces by means of the fixed point theorem of cone expansion and compression with norm type.

The theory of impulsive differential equations has been emerging as an important area of investigation in recent years (see [1–21]). In papers [22] and [23], we have discussed two infinite boundary value problems for nth-order impulsive nonlinear singular integro-differential equations of mixed type on the half-line in Banach spaces. By constructing a bounded closed convex set, apart from the singularities, and using the Schauder fixed point theorem, we obtain the existence of positive solutions for the infinite boundary value problems. But such equations are sublinear, and there are no results on existence of two positive solutions. In a recent paper [24], we discussed the existence of two positive solutions for a class of second order superlinear singular equations by means of different method, that is, by using the fixed point theorem of cone expansion and compression with norm type, which was established by the author in [25] (see also [26–29]). Now, in this paper, we extend the results of [24] to third-order equations in Banach spaces. The difficulty of this extension appears in two sides: we must introduce a new cone such that we can still use the fixed point theorem of cone expansion and compression with norm type, and, on the other hand, we need to introduce a suitable condition to guarantee the compactness of the corresponding operator. In addition, the construction of an example to show the application of our theorem to an infinite system of scalar equations is also difficult.

Let E be a real Banach space, and P be a cone in E that defines a partial ordering in E by \(x\leq y\) if and only if \(y-x\in P\). P is said to be normal if there exists a positive constant N such that \(\theta\leq x\leq y\) implies \(\|x\|\leq N\|y\|\), where θ denotes the zero element of E, and the smallest N is called the normal constant of P. If \(x\leq y\) and \(x\neq y\), then we write \(x< y\). Let \(P_{+}=P\backslash\{\theta\}\), that is, \(P_{+}=\{x\in P: x>\theta\}\). For details on cone theory, see [27].

Consider the infinite boundary value problem (IBVP) for third-order impulsive singular integro-differential equation of mixed type on the half-line in E:

where \(J=[0,\infty)\), \(J_{+}=(0,\infty)\), \(0< t_{1}<\cdots<t_{k}<\cdots\), \(t_{k}\rightarrow\infty\), \(J'_{+}=J_{+}\backslash\{t_{1},\ldots,t_{k},\ldots \}\), \(f\in C[J_{+}\times P_{+}\times P_{+}\times P_{+}\times P\times P,P]\), \(I_{k}, \bar{I}_{k}, \tilde{I}_{k}\in C[P_{+},P] \) (\(k=1,2,3,\ldots\)), \(\beta>1\), \(u''(\infty)=\lim_{t\rightarrow\infty}u''(t)\), and

\(K\in C[D,J]\), \(D=\{(t,s)\in J\times J: t\geq s\}\), \(H\in C[J\times J,J]\). \(\Delta u |_{t=t_{k}}\), \(\Delta u' |_{t=t_{k}}\), and \(\Delta u'' |_{t=t_{k}}\) denote the jumps of \(u(t)\), \(u'(t)\), and \(u''(t)\) at \(t=t_{k}\), respectively, that is,

where \(u(t_{k}^{+})\) and \(u(t_{k}^{-})\) represent the right and left limits of \(u(t)\) at \(t=t_{k}\), respectively, and \(u'(t_{k}^{+}) \) (\(u''(t_{k}^{+})\)) and \(u'(t_{k}^{-}) \) (\(u''(t_{k}^{-})\)) represent the right and left limits of \(u'(t) \) (\(u''(t)\)) at \(t=t_{k}\), respectively. In the following, we always assume that

and

that is, \(f(t,u,v,w,y,z)\) is singular at \(t=0\), \(u=\theta\), \(v=\theta \), and \(w=\theta\). We also assume that

and

that is, \(I_{k}(w)\), \(\bar{I}_{k}(w)\), and \(\tilde{I}_{k}(w) \) (\(k=1,2,3,\ldots\)) are singular at \(w=\theta\). Let \(PC[J,E]=\{u: u\mbox{ is a map from }J\mbox{ into }E\mbox{ such that } u(t)\mbox{ is continuous at }t\neq t_{k},\mbox{ left-continuous at }t=t_{k}, \mbox{and }u(t^{+}_{k})\mbox{ exists},k=1,2,3,\ldots\}\) and \(PC^{1}[J,E]= \{u\in PC[J,E]: u'(t)\mbox{ is continuous at }t\neq t_{k}, \mbox{and } u'(t_{k}^{+}) \mbox{ and }u'(t_{k}^{-})\mbox{ exist for }k=1,2,3,\ldots\}\). Let \(u\in PC^{1}[J,E]\). For \(0< h< t_{k}-t_{k-1}\), by the mean value theorem ([30], Theorem 1.1.1) we have

hence, it is easy to see that the left derivative of \(u(t)\) at \(t=t_{k}\), which is denoted by \(u'_{-}(t_{k})\), exists, and

In what follows, it is understood that \(u'(t_{k})=u'_{-}(t_{k})\). So, for \(u\in PC^{1}[J,E]\), we have \(u'\in PC[J,E]\). Let \(PC^{2}[J,E]=\{u\in PC[J,E]: u''(t)\mbox{ is continuous at }t\neq t_{k}, \mbox{and }u''(t_{k}^{+})\mbox{ and }u''(t_{k}^{-})\mbox{ }\mbox{exist for }k=1,2,3,\ldots\}\). For \(u\in PC^{2}[J,E]\), we have

so, observing the existence of \(u''(t_{k}^{-})\) and taking limits as \(h\rightarrow0^{+}\) in this equality, we see that \(u'(t_{k}^{-})\) exists and

Similarly, we can show that \(u'(t_{k}^{+})\) exists. Hence, \(u\in PC^{1}[J,E]\). Consequently, \(PC^{2}[J,E]\subset PC^{1}[J,E]\). For \(u\in PC^{2}[J,E]\), by using \(u'(t)\) and \(u''(t)\) instead of \(u(t)\) and \(u'(t)\) in (10) and (11) we get the conclusion: the left derivative of \(u'(t)\) at \(t=t_{k}\), which is denoted by \(u''_{-}(t_{k})\), exists, and \(u''_{-}(t_{k})=u''(t_{k}^{-})\). In what follows, it is understood that \(u''(t_{k})=u''_{-}(t_{k})\). Hence, for \(u\in PC^{2}[J,E]\), we have \(u'\in PC^{1}[J,E]\) and \(u''\in PC[J,E]\).

A map \(u\in PC^{2}[J,E]\cap C^{3}[J'_{+},E]\) is called a positive solution of IBVP (1) if \(u(t)>\theta\) for \(t\in J_{+}\) and \(u(t)\) satisfies (1). Now, we need to introduce a new space \(DPC^{2}[J,E]\) and a new cone Q in it. Let

It is easy to see that \(DPC^{2}[J,E]\) is a Banach space with norm

where

Let \(W=\{u\in DPC^{2}[J,E]: u(t)\geq\theta, u'(t)\geq\theta, u''(t)\geq\theta, \forall t\in J\}\) and

Obviously, W and Q are two cones in the space \(DPC^{2}[J,E]\), and \(Q\subset W\). Let \(Q_{+}=\{u\in Q: \|u\|_{D}>0\}\) and \(Q_{pq}=\{u\in Q: p\leq\|u\|_{D}\leq q\}\) for \(q>p>0\).

In the following, we always assume that the cone P is normal with normal constant N.

Remark 1

For \(u\in DPC^{2}[J,E]\), we have \(u(0)=\theta\) and \(u'(0)=\theta\). This is clear since \(u(0)\neq\theta\) implies

and \(u'(0)\neq\theta\) implies

Lemma 1

For \(u\in Q\), we have

and

where

Proof

The method of the proof is similar to that of Lemma 1 in [24], but it is more complicate. For \(u\in Q\), we need to establish six inequalities:

For example, we establish the first one. By Remark 1, \(u(0)=\theta\) and \(u'(0)=\theta\), so

Since

we have

and hence

From these six inequalities it is easy to prove inequalities (12)-(14). For example, we prove (12). We have

so,

and therefore

and hence, (12) holds. □

Corollary

For \(u\in Q_{+}\), we have \(u(t)>\theta\) and \(u'(t)>\theta\) for \(t\in J_{+}\) and \(u''(t)>\theta\) for \(t\in J\).

This follows from (12)-(14).

Let us list some conditions.

(H₁) \(\sup_{t\in J}\int_{0}^{t}K(t,s)s^{2}\,ds<\infty\), \(\sup_{t\in J}\int_{0}^{\infty}H(t,s)s^{2}\,ds<\infty\), and

In this case, let

(H₂) There exist \(a,b\in C[J_{+},J]\), \(g\in C[J_{+}\times P_{+},J]\), and \(G\in C[J_{+}\times J\times J,J]\) such that

and

for any \(q\geq p>0\), where

and

In this case, let (for \(q\geq p>0\))

where \(\beta'\) is defined by (15).

(H₃) \(I_{k}(w)\leq t_{k}\bar{I}_{k}(w)\) and \(\bar{I}_{k}(w)\leq t_{k}\tilde{I}_{k}(w)\), \(\forall w\in P_{+} \) (\(k=1,2,3,\ldots\)), and there exist \(\gamma_{k}\in J \) (\(k=1,2,3,\ldots\)) and \(F\in C[J_{+},J]\) such that

and

and, consequently,

In this case, let (for \(q\geq p>0\))

(H₄) For any \(t\in J_{+}\), \(r>p>0\), and \(q>0\), \(f(t,P_{pr},P_{pr},P_{pr},P_{q},P_{q})=\{f(t,u,v,w,y,z): u,v,w\in P_{pr}, y,z\in P_{q}\}\), \(I_{k}(P_{pr})=\{I_{k}(w): w\in P_{pr}\}\), \(\bar{I}_{k}(P_{pr})=\{\bar{I}_{k}(w): w\in P_{pr}\}\), and \(\tilde{I}_{k}(P_{pr})=\{\tilde{I}_{k}(w): w\in P_{pr}\} \) (\(k=1,2,3,\ldots\)) are relatively compact in E, where \(P_{pr}=\{w\in P: p\leq\|w\|\leq r\}\) and \(P_{q}=\{w\in P: \|w\|\leq q\}\).

(H₅) There exist \(w_{0}\in P_{+}\), \(c\in C[J_{+},J]\), and \(\tau\in C[P_{+},J]\) such that

and

and

(H₆) There exist \(w_{1}\in P_{+}\), \(d\in C[J_{+},J]\), and \(\sigma\in C[P_{+},J]\) such that

and

and

Remark 2

It is clear: if condition (H₁) is satisfied, then the operators T and S defined by (2) are bounded linear operators from \(DPC^{2}[J,E]\) into \(BC[J,E]\) (the Banach space of all bounded continuous maps from J into E with norm \(\|u\|_{B}=\sup_{t\in J}\|u(t)\|\)), and \(\|T\|\leq k^{*}\), \(\|S\|\leq h^{*}\); moreover, we have \(T(DPC^{2}[J,P])\subset BC[J,P]\) and \(S(DPC^{2}[J,P])\subset BC[J,P]\), \(DPC^{2}[J,P]=\{u\in DPC^{2}[J,E]: u(t)\geq\theta, \forall t\in J\}\) and \(BP[J,P]=\{u\in BP[J,E]: u(t)\geq\theta,\forall t\in J\}\).

Remark 3

Condition (H₅) means that the function \(f(t,u,v,w,y,z)\) is superlinear with respect to w.

Remark 4

Condition (H₆) means that the function \(f(t,u,v,w,y,z)\) is singular at \(w=\theta\), and it is stronger than (6).

Remark 5

If condition (H₃) is satisfied, then (7) implies (8), and (8) implies (9).

Remark 6

Condition (H₄) is satisfied automatically when E is finite-dimensional.

Remark 7

In what follows, we need the following three formulas (see [6], Lemma 2):

(a) If \(u\in PC[J,E]\cap C^{1}[J'_{+},E]\), then

(b) If \(u\in PC^{1}[J,E]\cap C^{2}[J'_{+},E]\), then

(c) If \(u\in PC^{2}[J,E]\cap C^{3}[J'_{+},E]\), then

We shall reduce IBVP (1) to an impulsive integral equation. To this end, we first consider the operator A defined by

In what follows, we write \(J_{1}=[0,t_{1}]\), \(J_{k}=(t_{k-1},t_{k}] \) (\(k=2,3,4,\ldots\)).

Lemma 2

If conditions (H₁)-(H₄) are satisfied, then operator A defined by (19) is a continuous operator from \(Q_{+}\) into Q; moreover, for any \(q>p>0\), \(A(Q_{pq})\) is relatively compact.

Proof

Let \(u\in Q_{+}\) and \(\|u\|_{D}=r\). Then \(r>0\), and, by (12)-(14) and Remark 1,

and

so, conditions (H₁) and (H₂) imply (for \(k^{*}\), \(h^{*}\), \(a(t)\), \(g_{p,q}(t)\), \(a_{p,q}^{*}\), \(G_{p,q}\), \(b(t)\), \(b^{*}\), see conditions (H₁) and (H₂))

where \(g_{r,r}(t)\) and \(G_{r,r}^{*}\) are \(g_{p,q}(t)\) and \(G_{p,q}^{*}\) for \(p=r\) and \(q=r\), respectively. By (20) and condition (H₂) we know that the infinite integral \(\int _{0}^{\infty}f(t,u(t),u'(t),u''(t),(Tu)(t),(Su)(t))\,dt\) is convergent and

On the other hand, by condition (H₃) we have

where \(N_{r,r}\) is \(N_{p,q}\) for \(p=r\) and \(q=r\), which implies the convergence of the infinite series \(\sum_{k=1}^{\infty}\tilde{I}_{k}(u''(t_{k}^{-}))\) and

From (19) we get

Moreover, by condition (H₃) we have

so, (19) gives

On the other hand, by (19) we have

so,

and, by condition (H₃),

In addition, (26) gives

so,

and

It follows from (25), (28), (31), (21), and (23) that \(Au\in DPC^{2}[J,E]\) and

Moreover, (24), (25), (27), (28), (30), and (31) imply

and

and hence, \(Au\in Q\). Thus, we have proved that A maps \(Q_{+}\) into Q.

Now, we are going to show that A is continuous. Let \(u_{n},\bar{u}\in Q_{+}\) and \(\|u_{n}-\bar{u}\|_{D}\rightarrow0 \) (\(n\rightarrow\infty\)). Write \(\|\bar{u}\|_{D}=2\bar{r} \) (\(\bar{r}>0\)), and we may assume that \(\bar{r}\leq\|u_{n}\|_{D}\leq3\bar{r} \) (\(n=1,2,3,\ldots\)). So, (12)-(14) imply

and

By (19) we have

When \(0< t\leq t_{1}\), we have

so,

and

It follows from (38)-(40) that

It is clear that

and, similarly to (20) and observing (35)-(37), we have

and by condition (H₂) we see that \(\int_{0}^{\infty}\sigma (t)\,dt<\infty\). Hence, the dominated convergence theorem implies

On the other hand, similarly to (22) and observing (37), we have

By (43) and condition (H₃), using a similar method in the proof of Lemma 2 of [24], we can prove

and

It follows from (41), (42), (44), and (45) that

On the other hand, similarly to (41) and observing (26) and (29), we easily get

and

So, (47), (48) and (42), (44), (45) imply

and

It follows from (46), (49), and (50) that \(\|Au_{n}-A\bar{u}\|_{D}\rightarrow 0\) as \(n\rightarrow\infty\), and the continuity of A is proved.

Finally, we prove that \(A(Q_{pq})\) is relatively compact, where \(q>p>0\) are arbitrarily given. Let \(\bar{u}_{n}\in Q_{pq}\) (\(n=1,2,3,\ldots\)). Then, by (12)-(14) and Remark 1, we have

Similarly to (20), (22), (32)-(34) and observing (51), we get

and

From (54) we see that the functions \(\{(A\bar{u}_{n})(t)\} \) (\(n=1,2,3,\ldots\)) are uniformly bounded on \([0,r]\) for any \(r>0\). Consider \(J_{i}=(t_{i-1},t_{i}]\) for any fixed i. By (19) we have

Since

and, similarly,

(57) implies

and, consequently, by (52), (53), condition (H₃), and (58) we get

From (59) we know that the maps \(\{w_{n}(t)\} \) (\(n=1,2,3,\ldots\)) defined by

(\((A\bar{u}_{n})(t_{i-1}^{+})\) denotes the right limit of \((A\bar{u}_{n})(t)\) at \(t=t_{i-1}\)) are equicontinuous on \(\bar{J}_{i}=[t_{i-1},t_{i}]\). On the other hand, for any \(\epsilon>0\), choose a sufficiently large \(\tau>0\) and a sufficiently large positive integer j such that

We have, by (60), (19), (52), (53), and (61),

and

It follows from (62)-(64) and [30], Theorem 1.2.3, that

where \(W(t)=\{w_{n}(t): n=1,2,3,\ldots\}\), \(V(s)=\{\bar{u}_{n}(s): n=1,2,3,\ldots\}\), \(V'(s)=\{\bar{u}'_{n}(s): n=1,2,3,\ldots\}\), \(V''(s)=\{\bar{u}''_{n}(s): n=1,2,3,\ldots\}\), \((TV)(s)=\{(T\bar{u}_{n})(s): n=1,2,3,\ldots\}\), \((SV)(s)=\{(S\bar{u}_{n})(s): n=1,2,3,\ldots\}\), and \(\alpha(U)\) denotes the Kuratowski measure of noncompactness of a bounded set \(U\subset E\) (see [30], Section 1.2). Since \(V(s),V'(s),V''(s)\subset P_{p^{*}r^{*}}\) for \(s\in J_{+}\) and \((TV)(s)\subset P_{q^{*}}\), \((SV)(s)\subset P_{q^{*}}\) for \(s\in J\), where \(p^{*}=\min\{\frac{1}{2}N^{-2}\beta^{-1}(2\beta -1)^{-1}ps^{2}, N^{-2}\beta^{-2}\beta'ps,N^{-2}\beta^{-2}\beta'p\}\), \(r^{*}=\max\{qs^{2}, qs, q\}\), and \(q^{*}=\max\{k^{*}q, h^{*}q\}\), we see that, by condition (H₄),

and

It follows from (65)-(67) that

which implies by virtue of the arbitrariness of ϵ that \(\alpha(W(t))=0\) for \(t\in\bar{J}_{i}\). Hence, by Ascoli-Arzela theorem (see [30], Theorem 1.2.5) we conclude that \(W=\{w_{n}: n=1,2,3,\ldots\}\) is relatively compact in \(C[\bar{J}_{i}, E]\), and therefore, \(\{w_{n}(t)\} \) (\(n=1,2,3,\ldots\)) has a subsequence that is convergent uniformly on \(\bar{J}_{i}\), so, \(\{(A\bar{u}_{n})(t)\} \) (\(n=1,2,3,\ldots\)) has a subsequence that is convergent uniformly on \(J_{i}\). Since i may be any positive integer, by the diagonal method, we can choose a subsequence \(\{(A\bar{u}_{n_{j}})(t)\} \) (\(j=1,2,3,\ldots\)) of \(\{(A\bar{u}_{n})(t)\} \) (\(n=1,2,3,\ldots\)) such that \(\{(A\bar{u}_{n_{j}})(t)\} \) (\(j=1,2,3,\ldots\)) is convergent uniformly on each \(J_{i} \) (\(i=1,2,3,\ldots\)). Let

By a similar method, we can prove that \(\{(A\bar{u}_{n_{j}})'(t)\} \) (\(j=1,2,3,\ldots\)) has a subsequence that is convergent uniformly on each \(J_{i} \) (\(i=1,2,3,\ldots\)). For simplicity of notation, we may assume that \(\{(A\bar{u}_{n_{j}})'(t)\} \) (\(j=1,2,3,\ldots\)) itself converges uniformly on each \(J_{i} \) (\(i=1,2,3,\ldots\)). Let

Again by a similar method, we can prove that \(\{(A\bar{u}_{n_{j}})''(t)\}\) (\(j=1,2,3,\ldots\)) has a subsequence that is convergent uniformly on each \(J_{i} \) (\(i=1,2,3,\ldots\)). Again for simplicity of notation, we may assume that \(\{(A\bar{u}_{n_{j}})''(t)\}\) (\(j=1,2,3,\ldots\)) itself converges uniformly on each \(J_{i}\) (\(i=1,2,3,\ldots\)). Let

By (68)-(70) and the uniformity of convergence we have

and so, \(\bar{w}\in PC^{2}[J,E]\). From (54)-(56) we get

and

Consequently, \(\bar{w}\in DPC^{2}[J,E]\), and

Let \(\epsilon>0\) be arbitrarily given. Choose a sufficiently large positive number η such that

For any \(\eta< t<\infty\), we have, by (29),

so, from (52) and (53) we get

which implies by (72) that

and, letting \(j\rightarrow\infty\) and observing (70) and (71), we get

On the other hand, since \(\{(A\bar{u}_{n_{j}})''(t)\}\) converges uniformly to \(\bar{w}''(t)\) on \([0,\eta]\) as \(j\rightarrow\infty\), there exists a positive integer \(j_{0}\) such that

and hence

Consequently,

and hence

It is clear that (19) and (26) imply

and

By the uniformity of convergence of \(\{(A\bar{u}_{n_{j}})(t)\}\) and \(\{(A\bar{u}_{n_{j}})'(t)\}\) we see that

and

so, (74) and (75) imply that limits \(\lim_{j\rightarrow\infty }I_{k}(\bar{u}''_{n_{j}}(t_{k}^{-})) \) (\(k=1,2,3,\ldots\)) and \(\lim_{j\rightarrow\infty}\bar{I}_{k}(\bar{u}''_{n_{j}}(t_{k}^{-}))\) (\(k=1,2,3,\ldots\)) exist and

Let

Then \(z_{k}\geq\theta\), \(\bar{z}_{k}\geq\theta \) (\(k=1,2,3,\ldots\)), and

By (53) and condition (H₃) we have

so,

For any given \(\epsilon>0\), by condition (H₃) we can choose a sufficiently large positive integer \(k_{0}\) such that

and then, choose another sufficiently large positive integer \(j_{1}\) such that

It follows from (77)-(80) that

and

and hence

By (16), (17), and (74)-(76) we have

and

which imply

and

Since

(82) and (83) imply

and

By (84), (85), (73), and (81) we get

It follows from (73) and (86) that \(\|A\bar{u}_{n_{j}}-\bar{w}\|_{D}\rightarrow0\) as \(j\rightarrow\infty\), and the relative compactness of \(A(Q_{pq})\) is proved. □

Lemma 3

Let conditions (H₁)-(H₄) be satisfied. Then \(u\in Q_{+}\cap C^{3}[J'_{+},E]\) is a positive solution of IBVP (1) if and only if \(u\in Q_{+}\) is a solution of the following impulsive integral equation:

that is, u is a fixed point of the operator A defined by (19).

Proof

The method of the proof is similar to that of Lemma 3 in [24], the difference is in using formula (18) instead of formula (17) with discussion in a Banach space. We omit the proof. □

Lemma 4

(Fixed point theorem of cone expansion and compression with norm type; see [25], Corollary 1, or [26], Theorem 3, or [27], Theorem 2.3.4; see also [28, 29])

Let P be a cone in a real Banach space E, and \(\Omega_{1}\), \(\Omega_{2}\) be two bounded open sets in E such that \(\theta\in\Omega_{1}\), \(\bar{\Omega}_{1}\subset \Omega_{2}\), where θ denotes the zero element of E, and \(\bar{\Omega}_{i} \) denotes the closure of \(\Omega_{i} \) (\(i=1,2\)). Let an operator \(A: P\cap(\bar{\Omega}_{2}\backslash\Omega_{1})\rightarrow P\) be completely continuous (i.e., continuous and compact). Suppose that one of the following two conditions is satisfied:

where \(\partial\Omega_{i} \) denotes the boundary of \(\Omega_{i} \) (\(i=1,2\));

Then A has at least one fixed point in \(P\cap(\bar{\Omega}_{2}\backslash\Omega_{1})\).

Theorem

Let conditions (H₁)-(H₆) be satisfied. Assume that there exists \(r>0 \) such that

where \(a_{r,r}^{*}\), \(G_{r,r}\), and \(N_{r,r}\) are \(a_{p,q}^{*}\), \(G_{p,q}\), and \(N_{p,q}\) for \(p=r\) and \(q=r\), respectively (for \(a_{p,q}^{*}\), \(G_{p,q}\), \(N_{p,q}\), \(b^{*}\), and \(\gamma^{*}\); see conditions (H₂) and (H₃)). Then IBVP (1) has at least two positive solutions \(u^{*},u^{**}\in Q_{+}\cap C^{3}[J'_{+},E]\) such that

and

Proof

By Lemma 2 and Lemma 3 the operator A defined by (19) is continuous from \(Q_{+}\) into Q and we need to prove that A has two fixed points \(u^{*}\) and \(u^{**}\) in \(Q_{+}\) such that \(0<\|u^{*}\|_{D}<r<\|u^{**}\|_{D}\).

By condition (H₅) there exists \(r_{1}>0\) such that

Choose

For \(u\in Q\), \(\|u\|_{D}=r_{2}\), we have, by (14) and (90), \(\|u''(t)\|\geq N^{-2}\beta^{-2}\beta'r_{2}>r_{1}\), \(\forall t\in J \), so, (29) and (89) imply

and, consequently, \(\|(Au)''(t)\|\geq r_{2}\), \(\forall t\in J \); hence,

By condition (H₆) there exists \(r_{3}>0\) such that

Choose

For \(u\in Q\), \(\|u\|_{D}=r_{4}\), we have, by (14) and (93), \(r_{3}>r_{4}\geq \|u''(t)\|\geq N^{-2}\beta^{-2}\beta'r_{4}>0 \), so, we get, by (29) and (92),

and, consequently, \(\|(Au)''(t)\|\geq r>r_{4}\), \(\forall t\in J \); hence,

On the other hand, for \(u\in Q\), \(\|u\|_{D}=r\), (32)-(34) imply

so, (88) implies

By (90) and (93) we know that \(0< r_{4}< r< r_{2}\), and, by Lemma 2 the operator A is completely continuous from \(Q_{r_{4}r_{2}}\) into Q; hence, (91), (94), (95), and Lemma 4 imply that A has two fixed points \(u^{*}, u^{**}\in Q_{r_{4}r_{2}}\) such that \(r_{4}<\|u^{*}\|_{D}<r<\|u^{**}\|_{D}\leq r_{2}\). The proof is complete. □

Example

Consider the infinite system of scalar third-order impulsive singular integro-differential equations of mixed type on the half-line:

Conclusion

The infinite system (96) has at least two positive solutions \(\{u^{*}_{n}(t)\} \) (\(n=1,2,3,\ldots\)) and \(\{u^{**}_{n}(t)\} \) (\(n=1,2,3,\ldots\)) such that

and

Proof

Let \(E=l^{1}=\{u=(u_{1},\ldots,u_{n},\ldots): \sum_{n=1}^{\infty}|u_{n}|<\infty\}\) with norm \(\|u\|=\sum_{n=1}^{\infty }|u_{n}|\) and \(P=\{u=(u_{1},\ldots,u_{n},\ldots)\in E: u_{n}\geq0, n=1,2,3,\ldots\} \). Then P is a normal cone in E with normal constant \(N=1\), and the infinite system (96) can be regarded as an IBVP of the form (1). In this situation, \(u=(u_{1},\ldots,u_{n},\ldots)\), \(v=(v_{1},\ldots,v_{n},\ldots)\), \(w=(w_{1},\ldots,w_{n},\ldots)\), \(y=(y_{1},\ldots,y_{n},\ldots)\), \(z=(z_{1},\ldots,z_{n},\ldots)\), \(t_{k}=k \) (\(k=1,2,3,\ldots\)), \(K(t,s)=e^{-(t+2)s}\), \(H(t,s)=(1+t+s)^{-4}\), \(\beta=2\), \(\beta'=\frac {2}{3}\), \(f=(f_{1},\ldots,f_{n},\ldots)\), \(I_{k}=(I_{k1},\ldots ,I_{kn},\ldots)\), \(\bar{I}_{k}=(\bar{I}_{k1},\ldots, \bar{I}_{kn},\ldots)\), and \(\tilde{I}_{k}=(\tilde{I}_{k1},\ldots,\tilde{I}_{kn},\ldots)\), in which

and

It is easy to see that \(f\in C[J_{+}\times P_{+}\times P_{+}\times P_{+}\times P\times P, P]\), \(I_{k}, \bar{I}_{k}, \tilde{I}_{k}\in C[P_{+}, P] \) (\(k=1,2,3,\ldots\)), and condition (H₁) is satisfied with \(k^{*}\leq4e^{-2}\) (by using the fact that the function \(\phi (s)=s^{2}e^{-s} \) (\(0\leq s<\infty\)) attains its maximum at \(s=2\)) and \(h^{*}\leq1\). We have by (97)

so, observing the inequality \(\sum_{n=1}^{\infty}\frac{1}{n^{2}}<2\), we get

which implies that condition (H₂) is satisfied for

and

with (for \(q\geq p>0\))

and

By (98)-(100) it is obvious that

so,

Moreover, from (100) we get

so,

which implies that condition (H₃) is satisfied for \(\gamma _{k}=k^{-2}3^{-k-4}\) and

with

On the other hand, (97) implies

and

so, we see that condition (H₅) is satisfied for

and condition (H₆) is satisfied for

In addition, by (97) we have

and

It follows from (108), (109), and (107) that

and

hence, (3), (4), (5), and (6) are satisfied, that is, \(f(t,u,v,w,y,z)\) is singular at \(t=0\), \(u=\theta\), \(v=\theta\), and \(w=\theta \) (\(\theta =(0,0,\ldots ,0,\ldots)\)). On the other hand, from (98)-(100) we get

and

so,

and

which imply that (7), (8), and (9) are satisfied, that is, \(I_{k}(w)\), \(\bar{I}_{k}(w)\), and \(\tilde{I}_{k}(w)\) are singular at \(w=\theta\). Now, we check that condition (H₄) is satisfied. Let \(t\in J_{+}\), \(r>p>0\), and \(q>0\) be fixed, and \(\{y^{(m)}\}\) be any sequence in \(f(t,P_{pr},P_{pr},P_{pr},P_{q},P_{q})\), where \(y^{(m)}=(y_{1}^{(m)},\ldots,y_{n}^{(m)},\ldots)\). Then, by (101) we have

So, \(\{y_{n}^{(m)}\}\) is bounded, and, by the diagonal method we can choose a subsequence \(\{m_{i}\}\subset\{m\}\) such that

which implies by (110) that

Consequently, \(\bar{y}=(\bar{y}_{1},\ldots,\bar{y}_{n},\ldots)\in l^{1}=E\). Let \(\epsilon>0\) be given. Choose a positive integer \(n_{0}\) such that

By (111) we can choose a positive integer \(i_{0}\) such that

It follows from (110)-(114) that

hence, \(y^{(m_{i})}\rightarrow\bar{y}\) in E as \(i\rightarrow\infty\). Thus, we have proved that \(f(t,P_{pr},P_{pr},P_{pr},P_{q},P_{q})\) is relatively compact in E. Similarly, we can prove that \(I_{k}(P_{pr})\), \(\bar{I}_{k}(P_{pr})\), and \(\tilde{I}_{k}(P_{pr}) \) (\(k=1,2,3,\ldots\)) are relatively compact in E. Hence, condition (H₄) is satisfied. Finally, we check that inequality (88) is satisfied for \(r=1\), that is,

Since

and

we have, by (103) and (104),

and

Moreover, (102) implies

and (105) implies

so,

and, observing (106), we have

Consequently,

Hence, (115) holds, and our conclusion follows from the theorem. □

Authors and Affiliations

1. Department of Mathematics, Shandong University, Jinan, Shandong, 250100, People’s Republic of China

   Dajun Guo

Corresponding author

Correspondence to Dajun Guo.

Competing interests

The author declares that they have no competing interests.

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