New oscillation criteria for second-order neutral differential equations with distributed deviating arguments

Moaaz, Osama; Park, Choonkil; Elabbasy, Elmetwally M.; Muhsin, Waed

doi:10.1186/s13661-021-01512-x

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Published: 26 March 2021

New oscillation criteria for second-order neutral differential equations with distributed deviating arguments

Osama Moaaz¹,
Choonkil Park ORCID: orcid.org/0000-0001-6329-8228²,
Elmetwally M. Elabbasy¹ &
…
Waed Muhsin¹

Boundary Value Problems volume 2021, Article number: 35 (2021) Cite this article

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Abstract

In this work, we create new oscillation conditions for solutions of second-order differential equations with continuous delay. The new criteria were created based on Riccati transformation technique and comparison principles. Furthermore, we obtain iterative criteria that can be applied even when the other criteria fail. The results obtained in this paper improve and extend the relevant previous results as illustrated by examples.

1 Introduction

The importance of studying delay differential equations DDEs is not limited to the theoretical side only, but the applications of this type of equations extend to many branches of applied science. In fact, the neutral DDEs arise in the examination of vibrating masses attached to an elastic bar, in the solution of variational problems with time delays, and in problems concerning electric networks containing lossless transmission lines (as in high speed computers), see [1, 2].

The great development in the study of asymptotic behavior of DDEs is easily noted in many works in recent times. Some of these works that are concerned with improving the oscillation criteria of DDEs are [3–6]. In addition, many improved methods and interesting results can be found in studies [7–23], which study the oscillatory behavior of the NDDEs of different order.

In this work, we discuss the oscillation properties of the second-order NDDE with distributed deviating arguments

$$ \bigl( r ( t ) \bigl( ( x+p\cdot x\circ \tau ) ^{\prime } ( t ) \bigr) ^{\alpha } \bigr) ^{ \prime }+\Lambda [ q\cdot f\circ x\circ g;a,b ] ( t ) =0, $$

(1.1)

where $t\geq t_{0}$ and

$$ \Lambda [ F;a,b ] ( t ) \overset{\mathrm{def}}{=}\int _{a}^{b}F ( t,s ) \,\mathrm{d}s. $$

Throughout this work, we assume that

$$ \aleph ( t ) \overset{\mathrm{def}}{=} ( x+p\cdot x \circ \tau ) ( t ) $$

and the following hypotheses hold:

($\mathrm{H}_{1}$):: α is a ratio of odd natural numbers, $r\in C ( [ t_{0},\infty ) , ( 0,\infty ) ) $, and
$$ \int _{t_{0}}^{\infty }r^{-1/\alpha } ( s ) \,\mathrm{d}s= \infty . $$
(1.2)
($\mathrm{H}_{2}$):: $p\in C ( [ t_{0},\infty ) ) $, $q\in C ( [ t_{0},\infty ) \times [ a,b ] ) $, $0\leq p ( t ) <1$, and $q ( t,s ) >0$ is not zero on any half line $[ t_{\ast },\infty ) \times [ a,b ] $ for all $t_{\ast }\geq t_{0}$.
($\mathrm{H}_{3}$):: $\tau \in C ( [ t_{0},\infty ) ,\mathbb{R} ) $, $g\in C ( [ t_{0},\infty ) \times [ a,b ] ,\mathbb{R} ) $, $\tau ( t ) \leq t$, $\lim_{t\rightarrow \infty }\tau ( t ) =\infty $, $g ( t,s ) \leq t$, $\lim_{t\rightarrow \infty }g ( t,s ) =\infty $ for $s\in [ a,b ] $, and g is strictly increasing with respect to t and s for all $s\in ( a,b ) $.
($\mathrm{H}_{4}$):: $f\in C ( ( -\infty ,\infty ) ) $ and $f ( x ) /x^{\alpha }\geq \kappa $ for $x\neq 0$, where κ is a positive constant.

For a solution of (1.1), we mean a function $x\in C ( [t_{x},\infty ) ) $, $t_{x}\geq t_{0}$, which has the property $\aleph ( t ) $ and $r ( t ) ( \aleph ^{\prime } ( t ) ) ^{\alpha }$ are continuously differentiable for $t\in {}[ t_{x},\infty )$ and satisfies (1.1) on $[t_{x},\infty )$. We focus only on the solutions of (1.1) which satisfy $\sup \{ \vert x ( t ) \vert :t_{x}\leq t\}>0$ for $t\geq t_{x}$. A solution x of (1.1) is called nonoscillatory if it is either eventually positive or eventually negative; otherwise it is called oscillatory.

In the next part of the introduction, we provide some related work that contributed to the development of the study of oscillatory behavior of NDDEs.

In 1985, Grammatikopoulos et al. [7] studied the asymptotic behavior of NDDE

$$ \bigl(x(t)+p(t)x(t-\tau _{0})\bigr)^{\prime \prime }+q(t)x(t-g_{0})=0. $$

(1.3)

They proved that all solutions of (1.3) are oscillatory if $p(t)\in [ 0,1 ] $ and

$$ \int _{t_{0}}^{\infty }q(v) \bigl(1-p(v-g_{0}) \bigr)\,\mathrm{d}v=\infty . $$

However, Erbe et al. [8] established the oscillation condition when $q(t)\geqslant q_{0}>0$, $p ( t ) \in [ p_{1},p_{2} ] $ and $p(t)$ is not eventually negative. Posteriorly, Grace and Lalli [9] studied the oscillation of the NDDE

$$ (r(t) \bigl(x(t)+p(t)x(t-\tau _{0})^{\prime } \bigr)^{\prime }+q(t)f\bigl(x(t-g_{0})\bigr)=0, $$

under the condition

$$ \int _{t_{0}}^{\infty } \biggl( \rho (s)q(s) \bigl(1-p(s-g_{0})\bigr)- \frac{r(s-g_{0})(\rho ^{\prime }(s))^{2}}{4\kappa \rho (s)} \biggr) \,\mathrm{d}s=\infty , $$

where $\rho \in C^{1} ( [ t_{0},\infty ) , ( 0, \infty ) ) $.

In the previous decade, under the hypothesis $\tau \circ g=g\circ \tau $, Han et al. [10] presented the oscillation criteria for the NDDE

$$ \bigl(r(t) \bigl(x(t)+p(t)x\bigl(\tau (t)\bigr)\bigr)^{\prime } \bigr)^{\prime }+q(t)x\bigl(g(t)\bigr))=0. $$

In 2012, by using the Riccati transformation technique, Liu et al. [11] and Wu et al. [12] obtained the oscillation conditions for the NDDE

$$ \bigl( r ( t ) \bigl\vert w^{\prime } ( t ) \bigr\vert ^{\alpha -1}w^{\prime } ( t ) \bigr) ^{ \prime }+q ( t ) \bigl\vert x \bigl( g ( t ) \bigr) \bigr\vert ^{\beta -1}x \bigl( g ( t ) \bigr) =0, $$

where $w ( t ) :=x(t)+p(t)x(\tau (t))$, $\alpha \geq \beta $, $r^{\prime } ( t ) >0$, and $g^{\prime } ( t ) >0$. Based on establishing new comparison theorems that compare the second-order equation with a first-order DDE, Baculikova and Dzurina [13] studied the NDDE

$$ \bigl( r(t) \bigl( \bigl( x(t)+p(t)x\bigl(\tau (t)\bigr) \bigr) ^{\prime } \bigr) ^{\alpha } \bigr) ^{\prime }+q(t)x^{\beta }\bigl(g(t) \bigr)=0, $$

(1.4)

under the conditions

$$ 0\leq p(t)\leq p_{0}< \infty ,\qquad \tau ^{\prime } ( t ) \geq \tau _{0},\quad \text{and}\quad \tau \circ g=g\circ \tau . $$

Of interesting works recently, Moaaz et al. in [14, 15] studied the oscillatory properties of (1.4) and improved the results in [13].

For NDDE with distributed deviating arguments (1.1), Candan [16] studied the sufficient conditions for the oscillation of solutions.

In this work, we are creating an improved relationship between the corresponding function ℵ and its first derivative. This new relationship helps us to get sharp criteria for testing the oscillation. Based on the Riccati transformation and comparison principles, we obtain new and different criteria for the oscillation of solutions of (1.1). The results obtained in this paper improve and extend the relevant previous results as illustrated by examples.

To prove our main results, we need the following auxiliary lemmas. The proof of the first lemma is similar to that of [13, Lemma 3] and hence we omit it.

Lemma 1.1

If x is a positive solution of (1.1) on $[ t_{0},\infty ) $, then there exists $t_{1}\geq t_{0}$ such that

$$ \aleph ( t ) >0, \qquad \aleph ^{\prime } ( t ) >0,\qquad \bigl( r ( t ) \bigl( \aleph ^{\prime } ( t ) \bigr) ^{\alpha } \bigr) ^{\prime }\leq 0 $$

(1.5)

for $t\geq t_{1}$.

Lemma 1.2

([14, Lemma 1.2])

Suppose that $F ( s ) =As-Bs^{(\alpha +1)/\alpha }$, where $A,B>0$ are constants. Then F attains its maximum value on $\mathbb{R} $ at $s^{\ast }= ( \alpha A\diagup ( ( \alpha +1 ) B ) ) ^{\alpha }$ and

$$ \max_{x\in r}F=F \bigl( s^{\ast } \bigr) = \frac{\alpha ^{\alpha }}{ ( \alpha +1 ) ^{\alpha +1}}\frac{A^{\alpha +1}}{B^{\alpha }}. $$

Remark 1.1

All functional inequalities are assumed to hold eventually, that is, they are satisfied for all $t>t_{1}$, where $t_{1}$ is large enough.

2 Main results

For convenience, we denote the class of all eventually positive solutions by $S^{+}$. Moreover, we assume the following notations: $\beta \overset{\mathrm{def}}{=} ( \alpha +1 ) ^{\alpha +1}$, $g_{a} ( t ) \overset{\mathrm{def}}{=}g ( t,a ) $,

$$\begin{aligned}& \Theta ( t ) \overset{\mathrm{def}}{=}\Lambda \bigl[ q \cdot ( 1-p\circ g ) ^{\alpha };a,b \bigr] ( t ) , \\& \mu ( t ) \overset{\mathrm{def}}{=} \int _{t_{1}}^{t}r^{-1/ \alpha } ( \theta ) \,\mathrm{d}\theta , \\& \widetilde{\mu }(t)\overset{\mathrm{def}}{=}\mu ( t ) + \frac{\kappa }{\alpha } \int _{t_{1}}^{t}\mu ( \theta ) \mu ^{ \alpha } \bigl( g(\theta ,a) \bigr) \Theta ( \theta ) \,\mathrm{d}\theta , \\& \widehat{\mu } ( t ) \overset{\mathrm{def}}{=}\exp \biggl( - \alpha \int _{g_{a} ( t ) }^{t} \frac{\mathrm{d}\theta }{\widetilde{\mu }(\theta )r^{1/\alpha } ( \theta ) } \biggr) , \end{aligned}$$

and $F_{+}(t)\overset{\mathrm{def}}{=}\max \{ 0,F(t) \} $, where $t_{1}\geq t_{0}$.

The following theorem gives a criterion for the oscillation of (1.1), depending on the comparison with a first-order DDE.

Theorem 2.1

Every solution of (1.1) is oscillatory if the first-order DDE

$$ \phi ^{\prime } ( t ) +\kappa \Theta ( t ) \widetilde{\mu }^{\alpha }\bigl(g_{a} ( t ) \bigr)\phi \bigl( g_{a} ( t ) \bigr) =0 $$

(2.1)

is oscillatory.

Proof

Assume the contrary that there is a nonoscillatory solution x of (1.1). Then we can assume $x\in S^{+}$, and so $x ( t )$, $x ( \tau ( t ) ) $, and $x ( g ( t,s ) ) $ are positive for $t\geq t_{1}\geq t_{0}$ and $s\in [ a,b ] $. It follows from Lemma 1.1 that (1.5) holds. Using the fact that $r ( t ) ( \aleph ^{\prime } ( t ) ) ^{\alpha }$ is a nonincreasing function, we get

$$ \int _{t_{1}}^{t} \biggl( \frac{r ( \theta ) ( \aleph ^{\prime } ( \theta ) ) ^{\alpha }}{r ( \theta ) } \biggr) ^{1/\alpha }\,\mathrm{d}\theta \geq \mu ( t ) \bigl( r ( t ) \bigl( \aleph ^{\prime } ( t ) \bigr) ^{\alpha } \bigr) ^{1/\alpha }, $$

and hence

$$ \aleph ( t ) \geq \mu ( t ) \bigl( r ( t ) \bigl( \aleph ^{\prime } ( t ) \bigr) ^{ \alpha } \bigr) ^{1/\alpha }. $$

(2.2)

It follows from (1.1) and (H₁) that

$$ \bigl( r ( t ) \bigl( \aleph ^{\prime } ( t ) \bigr) ^{\alpha } \bigr) ^{\prime }\leq -\kappa \int _{a}^{b}q ( t,s ) x^{\alpha } \bigl( g ( t,s ) \bigr) \,\mathrm{d}s. $$

(2.3)

From the definition of ℵ, we have

$$\begin{aligned} x \bigl( g ( t,s ) \bigr) =&\aleph \bigl( g ( t,s ) \bigr) -p \bigl( g ( t,s ) \bigr) x \bigl( \tau \bigl( g ( t,s ) \bigr) \bigr) \\ \geq &\aleph \bigl( g ( t,s ) \bigr) -p \bigl( g ( t,s ) \bigr) \aleph \bigl( \tau \bigl( g ( t,s ) \bigr) \bigr) \\ \geq &\aleph \bigl( g ( t,s ) \bigr) \bigl( 1-p \bigl( g ( t,s ) \bigr) \bigr) , \end{aligned}$$

which with (2.3) gives

$$\begin{aligned} \bigl( r ( t ) \bigl( \aleph ^{\prime } ( t ) \bigr) ^{\alpha } \bigr) ^{\prime } \leq &-\kappa \int _{a}^{b}q ( t,s ) \aleph ^{\alpha } \bigl( g ( t,s ) \bigr) \bigl[ 1-p \bigl( g ( t,s ) \bigr) \bigr] ^{ \alpha }\,\mathrm{d}s \\ \leq &-\kappa \aleph ^{\alpha } \bigl( g_{a} ( t ) \bigr) \int _{a}^{b}q ( t,s ) \bigl[ 1-p \bigl( g ( t,s ) \bigr) \bigr] ^{\alpha }\,\mathrm{d}s \\ \leq &-\kappa \Theta ( t ) \aleph ^{\alpha } \bigl( g_{a} ( t ) \bigr) , \end{aligned}$$

(2.4)

which is a direct result of the facts that $\aleph ^{\prime } ( t ) >0$ and $\partial _{s}g ( t,s ) >0$. Combining

$$ \mu \frac{\mathrm{d}}{\mathrm{d}t} \bigl( r^{1/\alpha }\aleph ^{ \prime } \bigr) ^{\alpha }=\mu \alpha \bigl( r^{1/\alpha }\aleph ^{ \prime } \bigr) ^{\alpha -1} \bigl( r^{1/\alpha }\aleph ^{\prime } \bigr) ^{\prime } $$

and

$$ \frac{\mathrm{d}}{\mathrm{d}t} \bigl( \aleph -\mu r^{1/\alpha } \aleph ^{\prime } \bigr) =\aleph ^{\prime }-\mu ^{\prime }r^{1/ \alpha } \aleph ^{\prime }-\mu \bigl( r^{1/\alpha }\aleph ^{\prime } \bigr) ^{\prime }=-\mu \bigl( r^{1/\alpha }\aleph ^{\prime } \bigr) ^{\prime }, $$

we get

$$ \frac{\mathrm{d}}{\mathrm{d}t} \bigl( \aleph -\mu r^{1/\alpha } \aleph ^{\prime } \bigr) =-\frac{1}{\alpha }\mu \bigl( r^{1/\alpha } \aleph ^{\prime } \bigr) ^{1-\alpha }\frac{\mathrm{d}}{\mathrm{d}t} \bigl( r^{1/\alpha }\aleph ^{\prime } \bigr) ^{\alpha }. $$

Thus, from (2.4), we find

$$ \frac{\mathrm{d}}{\mathrm{d}t} \bigl( \aleph ( t ) -\mu ( t ) r^{1/\alpha } ( t ) \aleph ^{\prime } ( t ) \bigr) \geq \frac{\kappa }{\alpha }\mu ( t ) \bigl( r^{1/\alpha } ( t ) \aleph ^{\prime } ( t ) \bigr) ^{1-\alpha } \Theta ( t ) \aleph ^{\alpha } \bigl( g_{a} ( t ) \bigr) . $$

(2.5)

Integrating (2.5) from $t_{1}\rightarrow t$, we have

$$ \aleph ( t ) \geq \mu ( t ) r^{1/\alpha } ( t ) \aleph ^{\prime } ( t ) + \frac{\kappa }{\alpha } \int _{t_{1}}^{t}\mu ( \theta ) \Theta ( \theta ) \bigl( r^{1/\alpha } ( \theta ) \aleph ^{\prime } ( \theta ) \bigr) ^{1- \alpha }\aleph ^{\alpha } \bigl( g(\theta ,a) \bigr) \,\mathrm{d} \theta . $$

(2.6)

Now, we set $\phi ( t ) :=r ( t ) ( \aleph ^{\prime } ( t ) ) ^{\alpha }$. Then, from (2.2) and (2.6), we obtain

$$\begin{aligned} \aleph ( t ) \geq &\mu ( t ) \phi ^{1/ \alpha } ( t ) + \frac{\kappa }{\alpha } \int _{t_{1}}^{t} \mu ( \theta ) \Theta ( \theta ) \phi ^{ ( 1-\alpha ) /\alpha } ( \theta ) \mu ^{ \alpha } \bigl( g(\theta ,a) \bigr) \phi \bigl( g(\theta ,a) \bigr) \,\mathrm{d}\theta \\ \geq &\mu ( t ) \phi ^{1/\alpha } ( t ) + \frac{\kappa }{\alpha } \int _{t_{1}}^{t}\mu ( \theta ) \Theta ( \theta ) \phi ^{ ( 1-\alpha ) /\alpha } ( \theta ) \mu ^{\alpha } \bigl( g(\theta ,a) \bigr) \phi ( \theta ) \,\mathrm{d}\theta \\ \geq &\phi ^{1/\alpha } ( t ) \biggl( \mu ( t ) +\frac{\kappa }{\alpha } \int _{t_{1}}^{t}\mu ( \theta ) \mu ^{ \alpha } \bigl( g(\theta ,a) \bigr) \Theta ( \theta ) \,\mathrm{d}\theta \biggr) \\ \geq &\widetilde{\mu }(t)\phi ^{1/\alpha } ( t ) . \end{aligned}$$

(2.7)

Combining (2.4) and (2.7), we have that ϕ is a positive solution of the first-order DD inequality

$$ \phi ^{\prime } ( t ) +\kappa \Theta ( t ) \widetilde{\mu }^{\alpha }\bigl(g_{a} ( t ) \bigr)\phi \bigl( g_{a} ( t ) \bigr) \leq 0. $$

From [24, Theorem 1], DDE (2.1) also has a positive solution, which is a contradiction. This contradiction completes the proof. □

Applying a well-known condition [25, Theorem 2.1.1] for oscillation of first-order DDE (2.1), we get immediately the following criteria for oscillation of (1.1).

Corollary 2.1

Every solution of (1.1) is oscillatory if one of the following conditions is satisfied:

$$ \underset{t\rightarrow \infty }{\lim \inf } \int _{g_{a} ( t ) }^{t}\widetilde{\mu }^{\alpha }\bigl(g_{a} ( \theta ) \bigr)\Theta ( \theta ) \,\mathrm{d}\theta >\frac{1}{\kappa \mathrm{e}} $$

(2.8)

or

$$ \underset{t\rightarrow \infty }{\lim \sup } \int _{g_{a} ( t ) }^{t}\widetilde{\mu }^{\alpha }\bigl(g_{a} ( \theta ) \bigr)\Theta ( \theta ) \,\mathrm{d}\theta >\frac{1}{\kappa }\quad \textit{and}\quad \partial _{t}g ( t,s ) \geq 0. $$

(2.9)

The next theorem gives another criterion for the oscillation of (1.1), depending on the Riccati transformation technique.

Theorem 2.2

Every solution of (1.1) is oscillatory if there is a positive function $\rho \in C^{1} ( [ t_{0},\infty ) ) $ satisfying

$$ \underset{t\rightarrow \infty }{\lim \sup } \int _{t_{1}}^{t} \biggl( \kappa \rho ( \theta ) \widehat{\mu } ( \theta ) \Theta ( \theta ) - \frac{r ( \theta ) ( \rho _{+}^{\prime } ( \theta ) ) ^{\alpha +1}}{\beta \rho ^{\alpha } ( \theta ) } \biggr) \,\mathrm{d}\theta =\infty , $$

(2.10)

where $t_{1}$ is sufficiently large.

Proof

Assume the contrary that there is a nonoscillatory solution x of (1.1). Then we can assume $x\in S^{+}$, and so $x ( t )$, $x ( \tau ( t ) ) $, and $x ( g ( t,s ) ) $ are positive for $t\geq t_{1}\geq t_{0}$ and $s\in [ a,b ] $. It follows from Lemma 1.1 that (1.5) holds. Now, we set

$$ w\overset{\mathrm{def}}{=}\rho r \biggl( \frac{\aleph ^{\prime }}{\aleph } \biggr) ^{\alpha }. $$

(2.11)

Thus, we note that $w ( t ) >0$ for $t\geq t_{1}$. By differentiating w, we get

$$\begin{aligned} w^{\prime } =&\rho ^{\prime }r \biggl( \frac{\aleph ^{\prime }}{\aleph } \biggr) ^{\alpha }+\rho \frac{ ( r\aleph ^{\prime } ) ^{\prime }}{\aleph ^{\alpha }}-\alpha \rho r \biggl( \frac{\aleph ^{\prime }}{\aleph } \biggr) ^{\alpha +1} \\ =&\frac{\rho ^{\prime }}{\rho }w+\rho \frac{ ( r\aleph ^{\prime } ) ^{\prime }}{\aleph ^{\alpha }}- \alpha \rho ^{-1/\alpha }r^{-1/\alpha }w^{1+1/\alpha }. \end{aligned}$$

(2.12)

Next, as in the proof of Theorem 2.1, we obtain (2.4) and (2.7). Then, from (2.7), we obtain $\aleph (t)\geq \widetilde{\mu }(t)r^{1/\alpha } ( t ) \aleph ^{\prime } ( t ) $ for $t\geq t_{1}$. Then, applying the Grönwall inequality, we find

$$ \aleph \bigl( g_{a} ( t ) \bigr) \geq \aleph ( t ) \exp \biggl[ - \int _{g_{a} ( t ) }^{t} \widetilde{\mu }^{-1}(\theta )r^{-1/\alpha } ( \theta ) \,\mathrm{d}\theta \biggr] =\widehat{\mu }^{1/\alpha } ( t ) \aleph ( t ) , $$

which with (2.4) gives

$$ \bigl( r ( t ) \bigl( \aleph ^{\prime } ( t ) \bigr) ^{\alpha } \bigr) ^{\prime }\leq -\kappa \Theta ( t ) \biggl( \frac{\aleph ( g_{a} ( t ) ) }{\aleph ( t ) } \biggr) ^{\alpha }\aleph ^{\alpha } ( t ) \leq -\kappa \Theta ( t ) \widehat{\mu } ( t ) \aleph ^{ \alpha } ( t ) . $$

(2.13)

Combining (2.12) and (2.13), we arrive at

$$ w^{\prime }\leq \frac{\rho _{+}^{\prime }}{\rho }w-\kappa \rho \Theta \widehat{\mu } ( t ) -\alpha \rho ^{-1/\alpha }r^{-1/ \alpha }w^{1+1/\alpha }. $$

(2.14)

Using Lemma 1.2 with $A=\rho _{+}^{\prime }/\rho $ and $B=\alpha ( \rho r ) ^{-1/\alpha }$, we get

$$ w^{\prime }\leq -\kappa \rho \Theta \widehat{\mu }+\frac{1}{\beta }r \bigl( \rho _{+}^{\prime } \bigr) ^{\alpha +1}\rho ^{-\alpha }. $$

(2.15)

Integrating (2.15) from $t_{1}\rightarrow t$, we find

$$ w ( t_{1} ) \geq \int _{t_{1}}^{t} \biggl( \kappa \rho ( \theta ) \Theta ( \theta ) \widehat{\mu } ( \theta ) -\frac{1}{\beta }r ( \theta ) \bigl( \rho _{+}^{\prime } ( \theta ) ^{\alpha +1} \bigr) \rho ^{-\alpha } ( \theta ) \biggr) \,\mathrm{d} \theta , $$

which contradicts (2.10). This contradiction completes the proof. □

It is easy to see that Corollary 2.1 cannot be applied in the case where

$$ \int _{g_{a} ( t ) }^{t}\widetilde{\mu }^{\alpha } \bigl(g_{a} ( \theta ) \bigr)\Theta ( \theta ) \,\mathrm{d} \theta \leq \frac{1}{\kappa \mathrm{e}}. $$

(2.16)

However, if $x\in S^{+}$ and (2.16) holds, then we can get a sharp estimate of $z ( g ( t ) ) /z ( t ) $. Thus, we can obtain a sharp criteria for the oscillation of (1.1).

Lemma 2.1

Assume that $x\in S^{+}$ and

$$ \underset{t\rightarrow \infty }{\lim \inf } \int _{g_{a} ( t ) }^{t}\widetilde{\mu }^{\alpha }\bigl(g_{a} ( \theta ) \bigr)\Theta ( \theta ) \,\mathrm{d}\theta \geq \delta $$

(2.17)

for some $\delta >0$. Then

$$ \frac{r ( g_{a} ( t ) ) }{r ( t ) } \biggl( \frac{\aleph ^{\prime } ( g_{a} ( t ) ) }{\aleph ^{\prime } ( t ) } \biggr) ^{\alpha }\geq \vartheta _{n} ( \delta ) $$

(2.18)

for every $n\geq 0$, where

$$ \vartheta _{m} ( \delta ) \overset{\mathrm{def}}{=} \textstyle\begin{cases} 1 & \textit{if }m=0; \\ \exp \bigl( \delta \vartheta _{m-1} ( \delta ) \bigr) & \textit{if } m>0. \end{cases} $$

(2.19)

Proof

The proof of the first lemma is similar to that of [26, Lemma 1], and hence we omit it. □

Theorem 2.3

Assume that (2.17) holds for some $\delta <0$. Every solution of (1.1) is oscillatory if there is a positive function $\rho \in C^{1} ( [ t_{0},\infty ) ) $ satisfying

$$ \underset{t\rightarrow \infty }{\lim \sup } \int _{t_{1}}^{t} \biggl( \kappa \rho ( \theta ) \Theta ( \theta ) - \frac{ ( \rho _{+}^{\prime } ( \theta ) ) ^{\alpha +1}r ( g_{a} ( \theta ) ) }{\beta \vartheta _{m} ( \delta ) \rho ^{\alpha } ( \theta ) ( g_{a}^{\prime }(\theta ) ) ^{\alpha }} \biggr) =\infty , $$

(2.20)

for some $m\geq 0$, where $\vartheta _{m}(\delta )$ is defined as (2.19).

Proof

Assume the contrary that there is a nonoscillatory solution x of (1.1). Then we can assume $x\in S^{+}$, and so $x ( t )$, $x ( \tau ( t ) ) $, and $x ( g ( t,s ) ) $ are positive for $t\geq t_{1}\geq t_{0}$ and $s\in [ a,b ] $. It follows from Lemma 1.1 that (1.5) holds. As in the proof of Theorem 2.1, we obtain (2.4). Now, we set

$$ \omega \overset{\mathrm{def}}{=}\rho r \biggl( \frac{\aleph ^{\prime }}{\aleph ( g_{a} ) } \biggr) ^{ \alpha }. $$

Thus, we note that $\omega (t)>0$ for $t\geq t_{1}$. By differentiating ω and using (2.4), we obtain

$$\begin{aligned} \omega ^{\prime } =&\rho ^{\prime }r \biggl( \frac{\aleph ^{\prime }}{\aleph ( g_{a} ) } \biggr) ^{ \alpha }+\rho \frac{(r(\aleph ^{\prime })^{\alpha })^{\prime }}{\aleph ^{\alpha } ( g_{a} ) }- \alpha \rho r\frac{ ( \aleph ^{\prime } ) ^{\alpha }}{\aleph ^{\alpha +1} ( g_{a} ) }\aleph ^{\prime } ( g_{a} ) g_{a}^{\prime } \\ \leq &\frac{\rho ^{\prime }}{\rho }\omega -\kappa \rho \Theta - \alpha \rho r\frac{ ( \aleph ^{\prime } ) ^{\alpha }}{\aleph ^{\alpha +1} ( g_{a} ) }\aleph ^{\prime } ( g_{a} ) g_{a}^{\prime }. \end{aligned}$$

Thus, it follows from Lemma 2.1 that

$$\begin{aligned} \omega ^{\prime } \leq &\frac{\rho ^{\prime }}{\rho }\omega -\kappa \rho \Theta - \alpha \rho \frac{r^{1+1/\alpha }\vartheta _{n}^{1/\alpha } ( \delta ) }{r^{1/\alpha } ( g_{a} ) } \biggl( \frac{\aleph ^{\prime }}{\aleph ^{\alpha +1} ( g_{a} ) } \biggr) ^{\alpha +1}g_{a}^{\prime } \\ \leq &\frac{\rho _{+}^{\prime }}{\rho }\omega -\kappa \rho \Theta - \alpha \frac{\vartheta _{n}^{1/\alpha } ( \delta ) g_{a}^{\prime }}{\rho ^{1/\alpha }r^{1/\alpha } ( g_{a} ) } \omega ^{1+1/\alpha }. \end{aligned}$$

(2.21)

Using Lemma 1.2 with $A=\rho _{+}^{\prime }/\rho $ and $B=\alpha \vartheta _{m}^{1/\alpha } ( \delta ) / ( \rho r ( g ) ) ^{1/\alpha }$, we get

$$ \omega ^{\prime }\leq -\kappa \rho \Theta + \frac{ ( \rho _{+}^{\prime } ) ^{\alpha +1}r ( g_{a} ) }{\beta \vartheta _{m} ( \delta ) \rho ^{\alpha } ( g_{a}^{\prime } ) ^{\alpha }}. $$

(2.22)

Integrating (2.22) from $t_{1}\rightarrow t$, we find

$$ \omega ( t_{1} ) \geq \int _{t_{1}}^{t} \biggl( \kappa \rho ( \theta ) \Theta ( \theta ) - \frac{ ( \rho _{+}^{\prime } ( \theta ) ) ^{\alpha +1}r ( g_{a} ( \theta ) ) }{\beta \vartheta _{m} ( \delta ) \rho ^{\alpha } ( \theta ) ( g_{a}^{\prime } ( \theta ) ) ^{\alpha }} \biggr) \,\mathrm{d}\theta , $$

which contradicts (2.20). This contradiction completes the proof. □

3 Further results

It is easy to notice that (2.7) is a sharper estimate than (2.2) for the relationship between ℵ and $\aleph ^{\prime }$. By repeating the same steps that improved (2.2), we obtain iterative criteria that can be applied even when the other criteria fail.

Lemma 3.1

Assume that $x\in S^{+}$. Then

$$ \aleph ( t ) \geq U_{k} ( t ) r^{1/\alpha } ( t ) \aleph ^{\prime } ( t ) $$

(3.1)

for $k=0,1,\ldots $ , where $U_{0} ( t ) :=\widetilde{\mu }(t)$ and

$$ U_{k+1} ( t ) := \int _{t_{1}}^{t} \biggl( \frac{1}{r ( s ) }\exp \biggl( \int _{s}^{t}\kappa \Theta ( \theta ) U_{n}^{ \alpha } \bigl( g_{a} ( \theta ) \bigr) \,\mathrm{d} \theta \biggr) \biggr) ^{1/\alpha }\,\mathrm{d}s. $$

(3.2)

Proof

Assume that $x\in S^{+}$. Then $x ( t )$, $x ( \tau ( t ) ) $, and $x ( g ( t,s ) ) $ are positive for $t\geq t_{1}\geq t_{0}$ and $s\in [ a,b ] $. It follows from Lemma 1.1 that (1.5) holds. By induction, we will prove (3.1).

Now, as in the proof of Theorem 2.1, we obtain (2.4) and (2.7). From (2.7), we obtain

$$ \aleph \geq \widetilde{\mu }(t)r^{1/\alpha }\aleph ^{\prime }=U_{0}r^{1/ \alpha } \aleph ^{\prime }. $$

Next, for $k=n$, we suppose that $\aleph \geq U_{n}r^{1/\alpha }\aleph ^{\prime }$. Hence, we get

$$ \aleph ( g_{a} ) \geq U_{n} ( g_{a} ) r^{1/ \alpha } ( g_{a} ) \aleph ^{\prime } ( g_{a} ) \geq U_{n} ( g_{a} ) r^{1/\alpha }\aleph ^{\prime }, $$

which with (2.4) gives

$$ \kappa \Theta ( t ) \aleph ^{\alpha } \bigl( g_{a} ( t ) \bigr) \bigl( r ( t ) \bigl( \aleph ^{\prime } ( t ) \bigr) ^{\alpha } \bigr) ^{\prime }+\kappa \Theta ( t ) U_{n}^{\alpha } \bigl( g_{a} ( t ) \bigr) r ( t ) \bigl( \aleph ^{\prime } ( t ) \bigr) ^{ \alpha }\leq 0. $$

(3.3)

Letting $H:=r ( \aleph ^{\prime } ) ^{\alpha }$, (3.3) reduces to

$$ H^{\prime } ( t ) +\kappa \Theta ( t ) U_{n}^{ \alpha } \bigl( g_{a} ( t ) \bigr) H ( t ) \leq 0. $$

(3.4)

Applying the Grönwall inequality in (3.4), we find

$$ H ( s ) \geq H ( t ) \exp \biggl( \int _{s}^{t} \kappa \Theta ( \theta ) U_{n}^{\alpha } \bigl( g_{a} ( \theta ) \bigr) \,\mathrm{d}\theta \biggr) $$

for $t\geq s\geq t_{1}$, and so

$$ \aleph ^{\prime } ( s ) \geq r^{1/\alpha } ( t ) \aleph ^{\prime } ( t ) \biggl( \frac{1}{r ( s ) }\exp \biggl( \int _{s}^{t}\kappa \Theta ( \theta ) U_{n}^{\alpha } \bigl( g_{a} ( \theta ) \bigr) \,\mathrm{d}\theta \biggr) \biggr) ^{1/\alpha }. $$

(3.5)

Integrating (3.5) from $t_{1}\rightarrow t$, we see that

$$\begin{aligned} \aleph ( t ) \geq &r^{1/\alpha } ( t ) \aleph ^{\prime } ( t ) \int _{t_{1}}^{t} \biggl( \frac{1}{r ( s ) }\exp \biggl( \int _{s}^{t}\kappa \Theta ( \theta ) U_{n}^{\alpha } \bigl( g_{a} ( \theta ) \bigr) \,\mathrm{d}\theta \biggr) \biggr) ^{1/\alpha } \,\mathrm{d}s \\ =&U_{n+1} ( t ) r^{1/\alpha } ( t ) \aleph ^{ \prime } ( t ) . \end{aligned}$$

This completes the proof. □

Theorem 3.1

Assume that $U_{k}$ are defined as in Lemma 3.1. Every solution of (1.1) is oscillatory if

$$ \int _{t_{0}}^{\infty }\Theta ( \theta ) U_{k} ( \theta ) \,\mathrm{d}\theta =\infty $$

(3.6)

for some $k=0,1,\ldots $ .

Proof

Assume the contrary that there is a nonoscillatory solution x of (1.1). Then we can assume $x\in S^{+}$, and so $x ( t )$, $x ( \tau ( t ) ) $, and $x ( g ( t,s ) ) $ are positive for $t\geq t_{1}\geq t_{0}$ and $s\in [ a,b ] $. It follows from Lemma 1.1 and 3.1 that (1.5) and (3.1) hold. As in the proof of Theorem 2.1, we obtain (2.4).

Now, we define w as in (2.11) with $\rho \equiv 1$. Proceeding as in the proof of Theorem 2.2 and substituting (2.7) with (3.1), we arrive at

$$ w^{\prime } ( t ) +\kappa \Theta ( t ) U_{k} ( t ) +\alpha r^{-1/\alpha } ( t ) w^{1+1/ \alpha } ( t ) \leq 0 $$

(3.7)

or

$$ w^{\prime } ( t ) +\kappa \Theta ( t ) U_{k} ( t ) \leq 0. $$

(3.8)

Integrating (3.8) from $t_{1}\rightarrow t$, we get

$$ w ( t ) \leq w ( t_{1} ) -\kappa \int _{t_{1}}^{t} \Theta ( \theta ) U_{k} ( \theta ) \,\mathrm{d}\theta . $$

Therefore, $w ( t ) \rightarrow -\infty $ as $t\rightarrow \infty $, which is a contradiction. This contradiction completes the proof. □

Theorem 3.2

Assume that $U_{k}$ are defined as in Lemma 3.1. Every solution of (1.1) is oscillatory if

$$ \lim \inf_{t\rightarrow \infty }\frac{1}{G ( t ) } \int _{t}^{ \infty }r^{-1/\alpha } ( \theta ) G^{1+1/\alpha } ( \theta ) \,\mathrm{d}\theta >\frac{1}{\beta ^{1/\alpha }}, $$

(3.9)

where

$$ G ( t ) \overset{\mathrm{def}}{=} \int _{t}^{\infty }\Theta ( \theta ) U_{k} ( \theta ) \,\mathrm{d} \theta . $$

Proof

Assume the contrary that there is a nonoscillatory solution x of (1.1). Then we can assume $x\in S^{+}$, and so $x ( t )$, $x ( \tau ( t ) ) $, and $x ( g ( t,s ) ) $ are positive for $t\geq t_{1}\geq t_{0}$ and $s\in [ a,b ] $. By the same procedure as in the proof of Theorem 3.1, we arrive at (3.7). Then, integrating (3.7) from $t\rightarrow v$, we find

$$ \int _{t}^{v}\Theta ( \theta ) U_{k} ( \theta ) \,\mathrm{d}\theta +\alpha \int _{t}^{v}r^{-1/\alpha } ( \theta ) w^{1+1/ \alpha } ( \theta ) \,\mathrm{d}\theta \leq w ( t ) -w ( v ) . $$

Letting $v\rightarrow \infty $, we get

$$ G ( t ) +\alpha \int _{t}^{\infty }r^{-1/\alpha } ( \theta ) w^{1+1/\alpha } ( \theta ) \,\mathrm{d} \theta \leq w ( t ) , $$

(3.10)

or equivalently,

$$ 1+\alpha \int _{t}^{\infty }r^{-1/\alpha } ( \theta ) G^{1+1/ \alpha } ( \theta ) \biggl( \frac{w ( \theta ) }{G ( \theta ) } \biggr) ^{1+1/ \alpha }\,\mathrm{d}\theta \leq \frac{w ( t ) }{G ( t ) }. $$

(3.11)

If we set $\varrho =\inf_{t\geq t_{1}} ( w(t)/G ( t ) ) $, then we note that $\varrho \geq 1$. However, from (3.9) and (3.11), we get

$$ \varrho \geq 1+\alpha \biggl( \frac{\varrho }{\alpha +1} \biggr) ^{ \frac{\alpha +1}{\alpha }}. $$

(3.12)

Therefore, relationship (3.12) can be modeled on the form

$$ \frac{\varrho }{\alpha +1}\geq \frac{1}{\alpha +1}+ \frac{\alpha }{\alpha +1} \biggl( \frac{\varrho }{\alpha +1} \biggr) ^{ \frac{\alpha +1}{\alpha }}, $$

which contradicts the possible values of ϱ and α. This contradiction completes the proof. □

For the following theorem, we need to define the sequence $\{ \phi _{n} ( t ) \} _{n=0}^{\infty }$ as

$$ \phi _{n} ( t ) \overset{\mathrm{def}}{=}\phi _{0} ( t ) +\alpha \int _{t}^{\infty }r^{-1/\alpha } ( \theta ) \phi _{n-1}^{1+1/\alpha } ( \theta ) \,\mathrm{d} \theta ,\quad n=1,2,3,\ldots, $$

(3.13)

and

$$ \phi _{0} ( t ) \overset{\mathrm{def}}{=}G ( t ) $$

for all $t\geq t_{1}\geq t_{0}$, where G is defined as in Theorem 3.2.

Lemma 3.2

Assume that $x\in S^{+}$ and w is defined as in (2.11) with $\rho \equiv 1$. Then $w ( t ) \geq \phi _{n} ( t ) $. In addition, there is a function $\phi \in C ( [ t_{1},\infty ) , ( 0,\infty ) ) $ such that $\lim_{n\rightarrow \infty }\phi _{n} ( t ) =\phi ( t ) $ and

$$ \phi ( t ) =\phi _{0} ( t ) +\alpha \int _{t}^{ \infty }r^{-1/\alpha } ( \theta ) \phi ^{1+1/\alpha } ( \theta ) \,\mathrm{d}\theta . $$

(3.14)

Proof

Assume that $x\in S^{+}$. Then $x ( t )$, $x ( \tau ( t ) ) $, and $x ( g ( t,s ) ) $ are positive for $t\geq t_{1}\geq t_{0}$ and $s\in [ a,b ] $. By the same procedure as in the proof of Theorem 3.2, we arrive at (3.10), and hence

$$ \phi _{0} ( t ) =G ( t ) \leq w ( t ) . $$

Thus, from the definition of $\phi _{n}(t)$, we note that $w(t)\geq \phi _{n}(t)$ for all $n>1$ and $t\geq t_{1}$. Since $\{\phi _{n}(t)\}_{n=0}^{\infty }$ is an increasing sequence and bounded from above, $\phi _{n}(t)$ converges to $\phi (t)$. By using Lebesgue’s monotone convergence theorem, if we take the limit of (3.13) as $n\rightarrow \infty $, then we obtain that (3.14) hold. The proof is complete. □

Theorem 3.3

Assume that $U_{k}$ are defined as in Lemma 3.1. Every solution of (1.1) is oscillatory if

$$ \underset{t\rightarrow \infty }{\lim \sup }\phi _{n}(t) \biggl( \int _{t_{0}}^{t}r^{- \frac{1}{\alpha }}(s)\,\mathrm{d}s \biggr) ^{\alpha }>1 $$

(3.15)

for some positive integers n.

Proof

Assume the contrary that there is a nonoscillatory solution x of (1.1). Then we can assume $x\in S^{+}$, and so $x ( t )$, $x ( \tau ( t ) ) $, and $x ( g ( t,s ) ) $ are positive for $t\geq t_{1}\geq t_{0}$ and $s\in [ a,b ] $. Now, we define w as in (2.11) with $\rho \equiv 1$. From the fact that $( r ( s ) ( \aleph ^{\prime } ( s ) ) ^{\alpha } ) ^{\prime }\leq 0$, we have

$$\begin{aligned} \aleph ( t ) =&\aleph ( t_{1} ) + \int _{t_{1}}^{t} \frac{1}{r^{1/\alpha } ( \theta ) } \bigl( r ( \theta ) \bigl( \aleph ^{\prime } ( \theta ) \bigr) ^{ \alpha } \bigr) ^{1/\alpha }\,\mathrm{d}\theta \\ \geq & \bigl( r ( t ) \bigl( \aleph ^{\prime } ( t ) \bigr) ^{\alpha } \bigr) ^{1/\alpha } \int _{t_{1}}^{t} \frac{1}{r^{1/\alpha } ( \theta ) }\,\mathrm{d} \theta , \end{aligned}$$

which with (2.11) gives

$$\begin{aligned} w ( t ) =&r ( t ) \bigl( \aleph ^{\prime } ( t ) \bigr) ^{\alpha } \aleph ^{-\alpha } ( t ) \\ \leq &r ( t ) \bigl( \aleph ^{\prime } ( t ) \bigr) ^{\alpha } \biggl( \bigl( r ( t ) \bigl( \aleph ^{ \prime } ( t ) \bigr) ^{\alpha } \bigr) ^{1/\alpha } \int _{t_{1}}^{t}\frac{1}{r^{1/\alpha } ( \theta ) }\,\mathrm{d} \theta \biggr) ^{- \alpha } \\ =& \biggl( \int _{t_{1}}^{t} \frac{1}{r^{1/\alpha } ( \theta ) }\,\mathrm{d}\theta \biggr) ^{-\alpha }. \end{aligned}$$

Thus,

$$ w ( t ) \biggl( \int _{t_{0}}^{t} \frac{1}{r^{1/\alpha } ( \theta ) }\,\mathrm{d} \theta \biggr) ^{\alpha }\leq \biggl( \frac{\int _{t_{0}}^{t}r^{-1/\alpha } ( \theta ) \,\mathrm{d}\theta }{\int _{t_{1}}^{t}r^{-1/\alpha } ( \theta ) \,\mathrm{d}\theta } \biggr) ^{\alpha }\leq 1 $$

for $t\geq t_{1}$. Taking into account Lemma 3.2, we get a contradiction with (3.15). This contradiction completes the proof. □

4 Examples

In this section, we apply our main results to some special cases of (1.1) and also compare our results with the previous related results.

Example 4.1

Consider the second-order NDDE

$$ \bigl( \bigl( \bigl( x ( t ) +p_{0}x\circ \tau \bigr) ^{ \prime } \bigr) ^{\alpha } \bigr) ^{\prime }+\Lambda \biggl[ \frac{q_{0}}{t^{\alpha +1}}\cdot ( x\circ g ) ^{\alpha };a,1 \biggr] =0, $$

(4.1)

where $p_{0}\in [ 0,1 ) $, $q_{0}>0$, $\delta \in [ 0,1 ) $, $\tau ( t ) =\eta t$, $\eta \in ( 0,1 ) $, and $g ( t,s ) =st$ for $s\in [ a,1 ] $. Obviously, we see that

$$ \begin{aligned} & b=1 ,\qquad r ( t ) \equiv 1 , \qquad p(t) \equiv p_{0} , \qquad q(t,s)\equiv q_{0}/t^{\alpha +1} \quad \mbox{and} \\ & f ( x ) \equiv x^{\alpha } , \quad \mbox{with constant } \kappa =1 .\end{aligned}$$

Therefore, it is easy to verify that

$$\begin{aligned}& \Theta ( t ) = \frac{q_{0}}{t^{\alpha +1}} ( 1-a ) ( 1-p_{0} ) ^{\alpha },\qquad \mu ( t ) =t,\qquad \widetilde{\mu }(t)= ( 1+\lambda ) t, \\& \widehat{\mu } ( t ) = a^{1/ ( 1+\lambda ) },\quad \text{and}\quad G ( t ) = \frac{\lambda a^{\alpha / ( 1+\lambda ) }}{a^{\alpha }}\frac{1}{t^{\alpha }}, \end{aligned}$$

where

$$ \lambda \overset{\mathrm{def}}{=}\frac{1}{\alpha }a^{\alpha } ( 1-a ) ( 1-p_{0} ) ^{\alpha }q_{0}. $$

Next, to apply Corollary 2.1, we must first check either condition (2.9) or (2.8). By substitution and a simple computation, we obtain

$$\begin{aligned} \begin{aligned} \underset{t\rightarrow \infty }{\lim \inf } \int _{g_{a} ( t ) }^{t}\widetilde{\mu }^{\alpha }\bigl(g_{a} ( \theta ) \bigr)\Theta ( \theta ) \,\mathrm{d}\theta &=\alpha \lambda ( 1+ \lambda ) ^{\alpha } \underset{t \rightarrow \infty }{\lim \inf } \int _{at}^{t} \frac{1}{\theta }\,\mathrm{d}\theta \\ &=\alpha \lambda ( 1+\lambda ) ^{\alpha }\ln \frac{1}{a}. \end{aligned} \end{aligned}$$

Thus, by using Corollary 2.1, (4.1) is oscillatory if

$$ \alpha \lambda ( 1+\lambda ) ^{\alpha }\ln \frac{1}{a}> \frac{1}{\mathrm{e}}. $$

On the other hand, condition (3.9) with $k=1$ reduces to

$$\begin{aligned} \lim \inf_{t\rightarrow \infty }\frac{1}{G ( t ) } \int _{t}^{ \infty }r^{-1/\alpha } ( \theta ) G^{1+1/\alpha } ( \theta ) \,\mathrm{d}\theta =& \biggl( \frac{\lambda }{\alpha } \frac{a^{\alpha +\alpha / ( 1+\lambda ) }}{\alpha } \biggr) ^{1/\alpha }\lim \inf_{t\rightarrow \infty }t^{\alpha } \int _{t}^{\infty }\frac{1}{\theta ^{\alpha +1}}\,\mathrm{d} \theta \\ =&\frac{1}{\alpha } \biggl( \frac{\lambda }{\alpha } \frac{a^{\alpha +\alpha / ( 1+\lambda ) }}{\alpha } \biggr) ^{1/\alpha }>\frac{1}{\beta ^{1/\alpha }}. \end{aligned}$$

From Theorem 3.2, equation (4.1) is oscillatory if

$$ \lambda a^{\alpha +\alpha / ( 1+\lambda ) }> \frac{\alpha ^{\alpha +2}}{\beta }. $$

Example 4.2

Consider the second-order NDDE

$$ \bigl( \bigl( \bigl( x ( t ) + ( 1-\delta ) x ( \eta t ) \bigr) ^{\prime } \bigr) ^{\alpha } \bigr) ^{ \prime }+\frac{q_{0}}{t^{\alpha +1}}x^{\alpha } ( \lambda t ) =0, $$

(4.2)

where $\delta \in ( 0,1 ] $, $q_{0}>0$, and $\eta ,\lambda \in ( 0,1 ) $. Obviously, we see that

$$ \begin{aligned} & a=0 , \qquad b=1 , \qquad r ( t ) \equiv 1 ,\qquad p(t)\equiv 1-\gamma , \qquad q(t,s)\equiv q_{0}/t^{\alpha +1} , \qquad \tau ( t ) \equiv \eta t , \\ & g ( t,s ) \equiv \lambda t \quad \mbox{and} \quad f ( x ) \equiv x^{\alpha } , \quad \mbox{with constant } \kappa =1 .\end{aligned}$$

Therefore, it is easy to verify that

$$ \Theta ( t ) =\delta ^{\alpha }q_{0} \frac{1}{t^{\alpha +1}},\qquad \mu ( t ) =t, \qquad U_{0}(t)= \biggl( 1+ \frac{1}{\alpha }\lambda ^{\alpha }\delta ^{\alpha }q_{0} \biggr) t $$

and

$$ U_{1} ( t ) =\lambda ^{\alpha / ( 1+\frac{1}{\alpha } \lambda ^{\alpha }\delta ^{\alpha }q_{0} ) }. $$

From Theorem 3.2, equation (4.1) is oscillatory if

$$ q_{0}\delta ^{\alpha }\lambda ^{\alpha / ( 1+\frac{1}{\alpha } \lambda ^{\alpha }\delta ^{\alpha }q_{0} ) }> \frac{\alpha ^{\alpha +1}}{\beta }. $$

(4.3)

Remark 4.1

Consider the special case of (4.2) where $\delta =1$, $\alpha =1/3$, and $\lambda =0.9$. The oscillation criteria in [13, Corollary 2] and [17, Corollary 2.1] reduce to $q_{0}>3.61643$ and $q_{0}>1.92916$, respectively. However, (4.3) reduces to $q_{0}>0.16131$. So, our results improve and extend some of the previous results.

5 Conclusion

The oscillation theory of DDEs has many applications in applied sciences. Thus, studying the oscillation of the solutions of these equations has practical importance besides the theoretical importance. In this study, we obtained different oscillation criteria with different techniques. These new criteria enable us to test the oscillation of a class of NDDEs with continuous delay. Our results extended to recently published works [14, 15], and also improved [13, 17].

Modeling by fractional-order differential equations has more advantages than by classical integer-order ones as it considers the effects of existence of time memory or long-range space interactions. So, it would be interesting to extend the results of this paper to the fractional delay differential equations. Moreover, it is interesting to study the periodicity behavior of solutions of the studied equation as an extension of the works [19, 23].

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Acknowledgements

The author is grateful to the editors and two anonymous referees for a very thorough reading of the manuscript and for pointing out some inaccuracies.

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This work was supported by the Basic Science Research Program through the National Research Foundation of Korea funded by the Ministry of Education, Science and Technology (NRF-2017R1D1A1B04032937).

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Department of Mathematics, Faculty of Science, Mansoura University, 35516, Mansoura, Egypt
Osama Moaaz, Elmetwally M. Elabbasy & Waed Muhsin
Research Institute for Natural Sciences, Hanyang University, Seoul, 04763, Korea
Choonkil Park

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Moaaz, O., Park, C., Elabbasy, E.M. et al. New oscillation criteria for second-order neutral differential equations with distributed deviating arguments. Bound Value Probl 2021, 35 (2021). https://doi.org/10.1186/s13661-021-01512-x

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Received: 01 April 2020
Accepted: 19 March 2021
Published: 26 March 2021
DOI: https://doi.org/10.1186/s13661-021-01512-x

New oscillation criteria for second-order neutral differential equations with distributed deviating arguments

Abstract

1 Introduction

Lemma 1.1

Lemma 1.2

Remark 1.1

2 Main results

Theorem 2.1

Proof

Corollary 2.1

Theorem 2.2

Proof

Lemma 2.1

Proof

Theorem 2.3

Proof

3 Further results

Lemma 3.1

Proof

Theorem 3.1

Proof

Theorem 3.2

Proof

Lemma 3.2

Proof

Theorem 3.3

Proof

4 Examples

Example 4.1

Example 4.2

Remark 4.1

5 Conclusion

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Acknowledgements

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