On the asymptotic behavior of fourth-order functional differential equations

The aim of this work is to study asymptotic properties of a class of fourth-order delay differential equations. Our results in this paper not only generalize some previous results, but also improve the earlier ones. Examples are considered to elucidate the main results.

This paper is concerned with the oscillatory behavior of solutions of nonlinear fourth-order differential equations of the type

where the following conditions are satisfied:

(A₁):

\(r\in C ( [ \tau_{0},\infty ) , ( 0,\infty ) ) \), \(r^{\prime} ( \tau ) >0\) and α is a quotient of odd positive integers;

(A₂):

\(q,g\in C( [ \tau_{0},\infty ) \times{[} a,b], \mathbb{R} )\), \(q(\tau,\xi)\geq0\), \(q(\tau,\xi)\) is not zero on any half line \([\tau _{\lambda},\infty)\times{[} a,b]\), \(\tau_{\lambda}\geq\tau _{0}\), \(g(\tau,\xi)\leq\tau\) for \(\tau\geq\tau_{0}\) and \(\xi\in {[} a,b]\), \(g(\tau,\xi)\) is continuous, nondecreasing with respect to ξ and \(\lim_{\tau\rightarrow\infty}g(\tau,\xi)=\infty\);

(A₃):

\(\sigma\in C([a,b],\mathbb{R} )\), σ is nondecreasing and the integral of equation (1.1) is in the Riemann-Stieltjes sense;

and the function \(f\in C ( \mathbb{R} ,\mathbb{R} ) \) satisfies one of the following conditions:

(S₁):

\(f ( x ) /x^{\alpha}\geq k_{1}>0\) for \(x\neq0\);

(S₂):

\(f^{\prime} ( x ) / \vert f ( x ) \vert ^{\frac{1-\alpha}{\alpha}}\geq k_{2}>0\) for \(x\neq0\) and \(f ( uv ) \geq u^{\alpha}f ( v ) \) for \(uv>0\).

By a solution of equation (1.1), we mean a function \(x(\tau )\in C[\tau_{x},\infty)\), \(\tau_{x}\geq\tau_{0}\) such that \(r ( \tau ) ( x^{\prime\prime\prime} ( \tau ) ) ^{\alpha}\) is continuously differentiable for all \(\tau\geq\tau _{x}\) and satisfies equation (1.1) for all \(\tau\in{[} \tau_{x},\infty)\) . Here, we consider only proper solutions \(x ( \tau ) \) to equation (1.1) with property \(\sup\{ \vert x(\tau) \vert :\tau\geq\tau\}>0\) for any \(\tau\geq\tau_{x}\). A solution of equation (1.1) is called oscillatory if it has arbitrary large zeros, otherwise it is called nonoscillatory.

In recent years there has been much research activity concerning the oscillation behavior of solutions of nonlinear differential equations (see [1–21]). In the last few years, many papers have appeared on the oscillatory theory of fourth-order differential equations (see [2, 16, 22–25]).

The aim of this paper is to study the oscillatory behavior of the solutions of nonlinear fourth-order differential equations (1.1) under the assumption

and we consider the function f with and without monotonicity. The results obtained essentially generalize the results from Zhang [24] and also improve some results from Baculykova [2]. Examples are provided to illustrate new results.

In order to discuss our main results, we need the following lemmas.

Lemma 1.1

[15]

If the function y satisfies \(y^{(i)} ( \tau ) >0\), \(i=0,1,\ldots,n\), and \(y^{ ( n+1 ) } ( \tau ) <0\), then

Lemma 1.2

[1]

Let \(y\in C^{n} ( [ \tau_{0},\infty ) , ( 0,\infty ) ) \). Assume that \(y^{ ( n ) } ( \tau ) \) is of fixed sign and not identically zero on \([ \tau _{0},\infty ) \) and that there exists \(\tau_{1}\geq\tau_{0}\) such that \(y^{ ( n-1 ) } ( \tau ) y^{ ( n ) } ( \tau ) \leq0\) for all \(\tau\geq\tau_{1}\). If \(\lim_{\tau \rightarrow\infty}y ( \tau ) \neq0\), then for every \(\mu\in ( 0,1 ) \) there exists \(\tau_{\mu}\geq\tau_{1}\) such that

In this section, we establish new oscillation criteria for solutions of equation (1.1). For the sake of convenience, we insert the following notation:

and \(F_{+} ( \tau ) =\max \{ 0,F ( \tau ) \} \).

Lemma 2.1

If \(x ( \tau ) \) is an eventually positive three times continuously differentiable function such that \(r ( \tau ) x^{\prime\prime\prime} ( \tau ) \) is continuously differentiable and \(( r ( \tau ) x^{\prime\prime\prime } ( \tau ) ) ^{\prime}\leq0\) for large t, then one of the following cases holds for large t:

The proof is immediate and hence is omitted.

Theorem 2.1

Assume that (1.2) and (S₁) hold. If there exist continuously differentiable functions \(\rho,\vartheta\in C ( [ \tau_{0},\infty ) , ( 0,\infty ) ) \) such that

and

for some \(\mu_{1},\mu_{2}\in ( 0,1 ) \), then every solution of (1.1) is oscillatory.

Proof

Let x be a nonoscillatory solution of equation (1.1) on the interval \([ \tau_{0},\infty ) \). Without loss of generality, we may assume that \(x ( \tau ) >0\). From Lemma 2.1, there exists \(\tau _{1}\geq\tau_{0}\) such that \(x ( \tau ) \) has one of the four cases (C₁)-(C₄) for \(\tau\geq\tau_{1}\). For Case (C₁), we define

Then \(\omega ( \tau ) >0\). By differentiating, we obtain

It follows from Lemma 1.2 that

for all \(\mu\in ( 0,1 ) \) and every sufficiently large τ. From (1.1), (A₂) and (S₁), we see that

Thus, by (2.5), (2.6) and (2.7), we get

From Lemma 1.1, we have that

Integrating this inequality from \(g ( \tau,a ) \) to τ, we get

which with (2.8) gives

By using the inequality

with \(A=\frac{\alpha\mu}{2}\frac{\tau^{2}}{ ( \rho ( \tau ) r ( \tau ) ) ^{1/\alpha}}\), \(B=\frac{\rho^{\prime } ( \tau ) }{\rho ( \tau ) }\) and \(z=\omega\), we get

This implies that

for every \(\mu\in ( 0,1 ) \) and all sufficiently large τ, which contradicts (2.1).

Consider Case (C₂) holds. From Lemma 1.1, we get that \(x ( \tau ) \geq\tau x^{\prime} ( \tau ) \), by integrating this inequality from \(g ( \tau,\xi ) \) to τ, we get

Hence, from (S₁), we have

Integrating (1.1) from τ to u and using \(x^{\prime} ( \tau ) >0\), we obtain

Letting \(u\rightarrow\infty \), we see that

and so,

Integrating again from τ to ∞, we get

Now, we define

Then \(w ( \tau ) >0\) for \(\tau\geq\tau_{1}\). By differentiating and using (2.13), we find

Thus, we obtain

Then we get

This contradicts (2.2).

Assume that Case (C₃) holds. Since \(r ( \tau ) ( x^{\prime\prime\prime} ( \tau ) ) ^{\alpha}\) is nonincreasing, we have that \(r ( s ) ( x^{\prime\prime\prime} ( s ) ) ^{\alpha}\leq r ( \tau ) ( x^{\prime\prime\prime} ( \tau ) ) ^{\alpha }\) for all \(s\geq\tau\geq\tau_{1}\). This yields

Integrating this inequality from τ to u, we get

Letting \(u\rightarrow\infty\), we see that

By integrating the last inequality from τ to ∞, we obtain

Integrating again from τ to ∞, we find

Next, we define

Thus, we see that \(\psi ( \tau ) <0\) and satisfies

Hence, from (1.1), (2.17) and (S₁), we have

Since \(g ( \tau,\xi ) \leq\tau\) and \(x^{\prime} ( \tau ) <0\), we have that \(x ( g ( \tau,\xi ) ) \geq x ( \tau ) \). Therefore, we get

From (2.18), we have

Multiplying (2.19) by \(R_{3}^{\alpha} ( \tau ) \) and integrating from \(\tau_{1}\) to τ, we obtain

which with (2.20) gives

Using inequality (2.11) with \(A=R_{3}\), \(B=1\) and \(z=-\psi\), we get

It follows that

but this contradicts (2.3).

In Case (C₄). In view of the proof of Case (C₃), we have (2.16) holds. From Lemma 1.2, we have that \(x ( \tau ) \geq\frac{\mu}{2}\tau^{2}x^{\prime \prime} ( \tau ) \) for all \(\mu\in ( 0,1 ) \) and every sufficiently large τ. Thus, from (A₂), there exists \(\tau_{2}\geq\tau_{1}\) such that

for \(\tau\geq\tau_{2}\). Next, we define

We note that \(\varphi ( \tau ) <0\) for \(\tau\geq\tau_{1}\). By differentiating and using (1.1), (A₃) and (S₁), we obtain

Hence, (2.21) yields

From (2.16), we get

Multiplying (2.23) by \(R_{1}^{\alpha} ( \tau ) \) and integrating from \(\tau_{2}\) to τ, we obtain

By following the same steps as in Case (C₃), we get that

which contradicts (2.4). This contradiction completes the proof of Theorem 2.1. □

Theorem 2.2

Assume that (1.2) and (S₂) hold, and let \(g ( \tau,\xi ) \) have a positive partial derivative on \(I\times {[} a,b]\) with respect to τ. If there exist continuously differentiable functions \(\rho,\vartheta\in C ( [ \tau _{0},\infty ) , ( 0,\infty ) ) \) such that

and

for some \(\mu_{1},\mu_{2}\in ( 0,1 ) \), then every solution of (1.1) is oscillatory.

Proof

Let x be a nonoscillatory solution of equation (1.1). Without loss of generality, we may assume that \(x ( \tau ) >0\). By Lemma 2.1, there exists \(\tau_{1}\geq\tau_{0}\) such that \(x ( \tau ) \) has one of the four cases (C₁)-(C₄) for \(\tau\geq \tau_{1}\). For Case (C₁), since \(g ( \tau,\xi ) \) is nondecreasing with respect to ξ, \(x^{\prime} ( \tau ) >0\) and \(f^{\prime } ( x ) >0\), we have that \(f ( x ( g ( \tau,a ) ) ) \leq f ( x ( g ( \tau,\xi ) ) ) \). Thus, from (1.1), we get

Now, we define

By differentiating and using (S₂), we get

From (A₂), there exists \(\tau_{2}\geq\tau_{1}\) such that \(g ( \tau,a ) \geq\tau_{1}\) for \(\tau\geq\tau_{2}\). Hence, from Lemma 1.2 and \(x^{ ( 4 ) }<0\), we obtain

for all \(\mu\in ( 0,1 ) \) and \(\tau\geq\tau_{2}\). Therefore, (2.28) yields

By following the same steps as in Case (C₁) of the proof of Theorem 2.1, we get a contradiction with (2.24).

For Case (C₂). From (1.1), (S₂) and (A₃), we obtain

By integrating this inequality from τ to ∞, we obtain

Since \(f^{\prime} ( x ) >0\), we get

Integrating again from τ to ∞, we have

Next, we define

Then \(w ( \tau ) >0\) for \(\tau\geq\tau_{1}\). By differentiating and using (2.13), we find

Since \(x^{\prime\prime} ( \tau ) <0\), we see that \(x^{\prime } ( g ( \tau,a ) ) >x^{\prime} ( \tau ) \)

Then we get

Integrating again from \(\tau_{2}\) to τ, we have

which contradicts (2.25).

If Case (C₃) holds. As in the proof of Case (C₃) of Theorem 2.1, we have that (2.16), (2.17) and (2.18) hold. Then we define

Thus, we see that \(\psi ( \tau ) <0\) and satisfies

Hence, from (1.1), (2.17) and (S₂), we have

Since \(x^{\prime} ( \tau ) <0\), we get \(f ( x ( g ( \tau,\xi ) ) ) \geq f ( x ( \tau ) ) \). Therefore, we obtain

From (2.18) and (S₂), we have

Multiplying (2.19) by \(f ( R_{3} ( \tau ) ) \) and integrating from \(\tau_{1}\) to τ, we obtain

Using inequality (2.11) with \(A=k_{2}f ( R_{3} ( s ) ) \), \(B=f^{\prime} ( R_{3} ( s ) ) \) and \(z=-\psi\), we get

but this contradicts (2.26).

In Case (C₄). In view of the proof of Case (C₄) of Theorem 2.1, we have (2.16) and (2.21) hold. By defining \(\varphi ( \tau ) \) as the form (2.22), we note that \(\varphi ( \tau ) <0\) for \(\tau\geq\tau _{1}\). Thus, from (1.1) and (A₂), we get

From (2.21) and (S₂), we see that

Hence, (2.31) yields

By following the same steps as in Case (C₃), we get that

which contradicts (2.27). This contradiction completes the proof of Theorem 2.2. □

Theorem 2.3

Assume that (1.2) and (S₁) hold. If the differential equations

and

are oscillatory for some \(\mu_{1},\mu_{2}\in ( 0,1 ) \), then every solution of (1.1) is oscillatory.

Proof

Proceeding as in the proof of Theorem 2.1, for Case (C₁), we have that (2.10) holds. Then, if \(\rho ( \tau ) =1\), we get

for all \(\mu\in ( 0,1 ) \). Hence, from [1], we see that (2.32) has a nonoscillatory solution for every \(\mu\in ( 0,1 ) \), which is a contradiction.

The rest of the proof is the same, and hence is omitted. □

From Corollary 1 in Dzurina [3], if

and

then equation

is oscillatory. In the following theorem, by using the results of Dzurina [3], we will establish new oscillation criteria for solutions of equation (1.1) under the conditions

Theorem 2.4

Assume that (1.2), (2.38) and (S₁) hold, and let (2.4) hold for some \(\mu_{2}\in ( 0,1 ) \). If

and

for some \(\mu_{1}\in ( 0,1 ) \), then every solution of (1.1) is oscillatory.

Example 2.1

Consider the fourth-order differential equation

where \(\delta>0\) is a constant. We note that

If we choose \(\rho ( \tau ) =\vartheta ( \tau ) =1\) and \(k_{1}=1\), then it easy to see that conditions (2.1), (2.2), (2.3) and (2.4) hold for \(\delta>\frac{81}{256}\). Thus, from Theorem 2.1, every solution of equation (2.42) is oscillatory for \(\delta>\frac{81}{256}\).

Example 2.2

Consider the delay differential equation

where \(b>0\). According to Corollary 4 in [2], equation (2.43) is oscillatory if \(b>\frac{2^{5}}{e}\). If we choose \(\rho ( \tau ) =\vartheta ( \tau ) =1\) and \(k_{1}=1\), then we conclude that (2.1) and (2.2) are satisfied and (2.3) and (2.4) hold for \(b>\frac{1}{4}\). Hence, by Theorem 2.1, every solution of equation (2.43) is oscillatory for \(b>\frac{1}{4}\). Then our results supplement and improve some results obtained in [2]. In particular, we consider the equation

where \(\gamma=\sin^{-1}\frac{7}{5\sqrt{2}}\). Since \(b=25\sqrt {2}e^{2\gamma }>\frac{1}{4}\), every solution of equation (2.44) is oscillatory. For example, \(x ( \tau ) =e^{2\tau}\sin(\tau)\) is a solution of equation (2.44). On the other hand, [24] showed that every nonoscillatory solution of

tends to zero as \(\tau\rightarrow\infty\), and we note that \(b= \frac{ e^{-1/2}}{16}<\frac{1}{4}\).

The authors express their sincere gratitude to the editors and the anonymous referee for careful reading of the original manuscript and useful comments.

Authors and Affiliations

1. Department of Mathematics, Faculty of Science, Mansoura University, Mansoura, 35516, Egypt

   Osama Moaaz & Elmetwally M Elabbasy

2. Department of Mathematics, Hadhramout University, Hadhramout, Yemen

   Omar Bazighifan

Corresponding author

Correspondence to Omar Bazighifan.

Competing interests

The authors declare that they have no competing interests.

Authors’ contributions

All authors read and approved the final manuscript.

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