Asymptotic behavior for third-order quasi-linear differential equations

In this paper, a class of third-order quasi-linear differential equations withcontinuously distributed delay is studied. Applying the generalized Riccatitransformation, integral averaging technique of Philos type and Young’sinequality, a set of new criteria for oscillation or certain asymptoticbehavior of nonoscillatory solutions of this equations is given. Our resultsessentially improve and complement some earlier publications.

Consider the following third-order quasi-linear differential equation:

We build up the following hypotheses firstly:

(H1) $a(t)\in C([t_0,\mathrm{\infty }),(0,\mathrm{\infty }))$ and ${\int }_{t_0}^{\mathrm{\infty }}a{(s)}^{-\frac{1}{\gamma }}ds=\mathrm{\infty }$;

(H2) $p(t,\mu )\in C([t_0,\mathrm{\infty })\times [a,b],[0,\mathrm{\infty }))$ and $0\le p(t)\equiv {\int }_a^{b}p(t,\mu )d\mu \le p<1$;

(H3) $\tau (t,\mu )\in C([t_0,\mathrm{\infty })\times [a,b],R)$ is not a decreasing function for μ andsuch that

(H4) $q(t,\xi )\in C([t_0,\mathrm{\infty }),(0,\mathrm{\infty }))$;

(H5) $\sigma (t,\xi )\in C([t_0,\mathrm{\infty })\times [a,b],R)$ is not a decreasing function for ξ andsuch that

(H6) $f(x)\in C(R,R)$ and $\frac{f(x)}{x^{\gamma }}\ge \delta >0$;

(H7) γ is a quotient of odd positive integers.

Define the function by

A function $x(t)$ is a solution of (1) means that$x(t)\in C^2[T_x,\mathrm{\infty })$, $T_x\ge t_0$, $a(t){(z^{″}(t))}^{\gamma }\in C^1[T_x,\mathrm{\infty })$ and satisfies (1) on $[T_x,\mathrm{\infty })$. In this paper, we restrict our attention to thosesolutions of Eq. (1) which satisfy $sup\{|x(t)|:t\ge T\}>0$ for all $T\ge T_x$. We assume that Eq. (1) possesses such asolution. A solution of Eq. (1) is called oscillatory on $[T_x,\mathrm{\infty })$ if it is eventually positive or eventually negative;otherwise, it is called nonoscillatory.

In recent years, there has been much research activity concerning the oscillationtheory and applications of differential equations; see [1–4] and the reference contained therein. Especially, the study content ofoscillatory criteria of second-order differential equations is very rich. Incontrast, the study of oscillatory criteria of third-order differential equations isrelatively less, but most of works are about delay equations. Some interestingresults have been obtained concerning the asymptotic behavior of solutions of Eq.(1) in the particular case. For example, [5] consider the third-order functional differential equations of the form

Zhang et al.[6] focus on the following the third-order neutral differential equationswith continuously distributed delay:

Baculíková and Džurina [7] are concerned with the couple of the third-order neutral differentialequations of the form

However, as we know, oscillatory behaviors of solutions of Eq. (1) have not beenconsidered up to now. In this paper, we try to discuss the problem of oscillatorycriteria of Philos type of Eq. (1). Applying the generalized Riccati transformation,integral averaging technique of Philos type, Young’s inequality,etc., we obtain some new criteria for oscillation or certain asymptoticbehavior of nonoscillatory solutions of this equations. We should point out thatγ is any quotient of odd positive integers in this paper, but itis required that $\gamma =1$ in [6].

We start our work with the classification of possible nonoscillatory solutions of Eq.(1).

Lemma 2.1 Let$x(t)$be a positive solution of (1), and$z(t)$is defined as in (4). Then$z(t)$has only one of the following two properties eventually:

1. (I)

   $z(t)>0$, $z^{\prime }(t)>0$, $z^{″}(t)>0$;

2. (II)

   $z(t)>0$, $z^{\prime }(t)<0$, $z^{″}(t)>0$.

Proof Let $x(t)$ be a positive solution of (1), eventually (if it iseventually negative, the proof is similar). Then ${[a(t){(z^{″}(t))}^{\gamma }]}^{\prime }<0$. Thus, $a(t){(z^{″}(t))}^{\gamma }$ is decreasing and of one sign and it followshypotheses (H2)-(H7) that there exists $t_1\ge t_0$ such that $z^{″}(t)$ is of fixed sign for $t\ge t_1$. If we admit $z^{″}(t)<0$, then there exists a constant $M>0$ such that

Integrating from $t_1$ to t, we get

Let $t\to \mathrm{\infty }$ and using (H1), we have $z^{\prime }(t)\to -\mathrm{\infty }$. Thus $z^{\prime }(t)<0$ eventually, which together with$z^{″}(t)<0$ implies $z(t)<0$, which contradicts our assumption$z(t)>0$. This contradiction shows that$z^{″}(t)>0$, eventually. Therefore $z^{\prime }(t)$ is increasing and thus (I) or (II) holds for$z(t)$, eventually. □

Lemma 2.2 Let$x(t)$be a positive solution of (1), and correspondingly$z(t)$has the property (II). Assume that

Then

Proof Let $x(t)$ be a positive solution of Eq. (1). Since$z(t)$ satisfies the property (II), it is obvious that thereexists a finite limit

Next, we claim that $l=0$. Assume that $l>0$, then we have $l<z(t)<l+\epsilon$ for all $\epsilon >0$ and t enough large. Choosing$\epsilon <l(1-p)/p$, we obtain

where $K=\frac{l-p(l+\epsilon )}{l+\epsilon }>0$. □

Combining (H6), (13) with (1), one can get

where $q_1(t)={\int }_c^{d}q(t,\xi )d\xi$ and ${\sigma }_0(t)=\sigma (t,d)$. Integrating inequality (14) from t to∞, we get immediately

Using $z({\sigma }_0(s))>l$, we have

We have a contradiction with (10) and so it follows that ${lim}_{t\to \mathrm{\infty }}z(t)=0$, which implies that

Lemma 2.3[7]

Assume that$u(t)>0$, $u^{\prime }(t)>0$, $u^{″}(t)<0$on$[t_0,\mathrm{\infty })$. Then, for each$\alpha \in (0,1)$, there exists$T_{\alpha }\ge t_0$such that

Lemma 2.4[8]

Let$z(t)>0$, $z^{\prime }(t)>0$, $z^{″}(t)>0$, $z^{‴}(t)<0$on$[T_{\alpha },\mathrm{\infty })$. Then there exist$\beta \in (0,1)$and$T_{\beta }\ge T_{\alpha }$such that

For simplicity, we introduce the following notations:

A function $H\in C^1(D,R)$ is said to belong to X class$(H\in X)$ if it satisfies

1. (i)

   $H(t,t)=0$, $t\ge t_0$; $H(t,s)>0$, $(t,s)\in D_0$;

2. (ii)

   $\frac{\partial H(t,s)}{\partial s}<0$, there exist $\rho \in C^1([t_0,\mathrm{\infty }),(0,\mathrm{\infty }))$ and $h\in C(D_0,R)$ such that

   $$\frac{\partial H(t,s)}{\partial s}+\frac{{\rho }^{\prime }(t)}{\rho (t)}H(t,s)=-h(t,s){(H(t,s))}^{\frac{\gamma }{1+\gamma }}.$$

   (21)

Theorem 3.1 Assume that (10) holds, there exist$\rho \in C^1([t_0,\mathrm{\infty }),(0,\mathrm{\infty }))$and$H\in X$such that

Suppose, further, that$a^{\prime }(t)>0$. Then every solution$x(t)$of Eq. (1) is either oscillatory or converges to zero.

Proof Assume that Eq. (1) has a nonoscillatory solution$x(t)$. Without loss of generality, we may assume that$x(t)>0$, $t\ge t_1$, $x(\tau (t,\mu ))>0$, $(t,\mu )\in [t_0,\mathrm{\infty })\times [a,b]$, $x(\sigma (t,\xi ))>0$, $(t,\xi )\in [t_0,\mathrm{\infty })\times [c,d]$, $z(t)$ is defined as in (4). By Lemma 2.1, we have that$z(t)$ has the property (I) or the property (II). If$z(t)$ has the property (II). Since (10) holds, then theconditions in Lemma 2.2 are satisfied. Hence ${lim}_{t\to \mathrm{\infty }}x(t)=0$.

When $z(t)$ has the property (I), we obtain

Using (H5) and (H6), we have

where $q_1(t)={\int }_c^{d}q(t,\xi )d\xi$ and ${\sigma }_1(t)=\sigma (t,c)$. Let

Then

Choosing $u(t)=z^{\prime }(t)$ in Lemma 2.2, we obtain

Using Lemma 2.3, we get

Combining with (27)-(29), we have

where $Q(t)$ is defined by (23). Let

For $t\ge t_2\ge T_{\beta }$, we have

where $F(t,s)=w(s)H^{\frac{\gamma }{\gamma +1}}(t,s)$. By Young’s inequality

we obtain

Applying (33) to inequality (31), we obtain

Therefore, we have

The last inequality contradicts (22). □

Theorem 3.2 Assume that other conditions of Theorem 3.1 are satisfied exceptcondition (22). Further, for every T, the following inequalities hold:

and

If there exists $\psi \in C([t_0,\mathrm{\infty }),R)$ such that

where${\psi }_{+}(s)=max\{\psi (s),0\}$, then every solution$x(t)$of Eq. (1) is either oscillatory or converges to zero.

Proof As the proof of Theorem 3.1, we can see that (31) holds. It followsthat

where $G(t,s)=\frac{a(s)\rho (s)h^{\gamma +1}(t,s)}{{(\gamma +1)}^{\gamma +1}}$.

By (45), we get

and hence

Define the functions $\alpha (t)$ and $\beta (t)$ as follows:

From (37) and (42), we obtain

The remainder of the proof is similar to the theorem given in [9–11] and hence is omitted. If $z(t)$ has the property (II), since (10) holds, by Lemma2.2, we have ${lim}_{t\to \mathrm{\infty }}x(t)=0$. □

Theorem 3.3 If we replace (37) by

and assume that the other assumptions of Theorem 3.2 hold,then every solution of Eq. (1) is either oscillatory or convergesto zero.

Proof The proof is similar to Theorem 3.2 and hence isomitted. □

Remark 3.4 When $\gamma =1$, Theorems 3.1-3.3 with condition (37) reduce toTheorems 3.1-3.3 of Zhang [6], respectively.

The authors would like to thank Prof. Yuanhong Yu and the anonymous reviewer fortheir constructive and valuable comments, which have contributed much to theimproved presentation of this paper. This work was supported by the NationalScience and Technology Major Projects of China (Grant No. 2012ZX10001001-006),the National Natural Science Foundation of China (Grant No. 11101053, 7117102471371195), the Scientific Research Fund of Hunan Provincial Education Departmentof China (Grant No. 11A008) and the Planned Science and Technology Project ofHunan Province of China (Grant No. 2012SK3098, 2013SK3143).

Authors and Affiliations

1. College of Mathematics and Computing Science, Changsha University of Science and Technology, Changsha, Hunan, 410004, China

   Guixiang Qin, Chuangxia Huang & Yongqin Xie

2. School of Business, Central South University, Changsha, Hunan, 410083, China

   Fenghua Wen

Corresponding author

Correspondence to Fenghua Wen.

Competing interests

The authors declare that they have no competing interests.

Authors’ contributions

The work presented here was carried out in collaboration between all authors. GQcarried out the design of the study and drafted the manuscript. CH and YX conceived,instructed the design of the study and polished the manuscript. FW participated indiscussion and completed the revision of the manuscript. All authors read andapproved the final manuscript.

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