Oscillatory Solutions to Neutral Delay Differential Equations

Alsharari, Fahad; Bazighifan, Omar; Nofal, Taher A.; Khedher, Khaled Mohamed; Raffoul, Youssef N.

doi:10.3390/math9070714

Open AccessArticle

Oscillatory Solutions to Neutral Delay Differential Equations

by

Fahad Alsharari

^1,†

,

Omar Bazighifan

^2,*,†

,

Taher A. Nofal

^3,†,

Khaled Mohamed Khedher

^4,5,†

and

Youssef N. Raffoul

^6,*,†

¹

Department of Mathematics, College of Science and Human Studies, Hotat Sudair, Majmaah University, Majmaah 11952, Saudi Arabia

²

Department of Mathematics, Faculty of Science, Hadhramout University, Hadhramout 50512, Yemen

³

Department of Mathematics and Statistics, College of Science, Taif University, P.O. Box 11099, Taif 21944, Saudi Arabia

⁴

Department of Civil Engineering, College of Engineering, King Khalid University, Abha 61421, Saudi Arabia

⁵

Department of Civil Engineering, High Institute of Technological Studies, Mrezgua University Campus, Nabeul 8000, Tunisia

⁶

Department of Mathematics, University of Dayton, 300 College Park, Dayton, OH 45469, USA

^*

Authors to whom correspondence should be addressed.

^†

These authors contributed equally to this work.

Mathematics 2021, 9(7), 714; https://doi.org/10.3390/math9070714

Submission received: 14 February 2021 / Revised: 28 February 2021 / Accepted: 2 March 2021 / Published: 25 March 2021

(This article belongs to the Special Issue Recent Advances in Delay Differential and Difference Equations)

Download Versions Notes

Abstract

:

This article aims to mark out new conditions for oscillation of the even-order Emden–Fowler neutral delay differential equations with neutral term

{(β_{1} (ı) Φ_{α} [ζ^{(r - 1)} (ı)])}^{'} + β_{3} (ı) Φ_{α} [ς (ξ (ı))] = 0 .

The obtained results extend, and simplify known conditions in the literature. The results are illustrated with examples.

Keywords:

oscillation; even-order

1. Introduction

Over the past few years, oscillation of Emden–Fowler-Type neutral delay differential equations with are attracting a lot of attention. As a matter of fact, natural of differential equation appear in the study of several real world problems such as biological systems, population dynamics, pharmacoki-netics, theoretical physics, biotechnology processes, chemistry, engineering, control, see [1,2,3,4,5,6,7].

In this manuscript, we investigate the oscillation of the following even-order Emden-Fowler neutral differential equations:

{(β_{1} (ı) Φ_{α} [ζ^{(r - 1)} (ı)])}^{'} + β_{3} (ı) Φ_{α} [ς (ξ (ı))] = 0, ı \geq ı_{0},

(1)

where

ζ (ı) : = ς (ı) + \hat{β} (ı) ς (ϱ (ı)) .

Throughout this paper, we make the hypotheses as follows:

\{\begin{matrix} Φ_{α} [s] = {| s |}^{α - 1} s, β_{1} \in C [ı_{0}, \infty), β_{1} (ı) > 0, β_{1}^{'} (ı) \geq 0, \\ ϱ \in C^{1} [ı_{0}, \infty), ξ \in C [ı_{0}, \infty), ϱ^{'} (ı) > 0, ϱ (ı) \leq ı, lim_{ı \to \infty} ϱ (ı) = lim_{ı \to \infty} ξ (ı) = \infty, \\ \hat{β}, β_{3} \in C [ı_{0}, \infty), β_{3} (ı) > 0, 0 \leq \hat{β} (ı) < {\hat{β}}_{0} < \infty, \\ r \geq 4 is an even natural number, r is a quotient of odd positive integers . \end{matrix}

The following relations are satisfied

\int_{ı_{0}}^{\infty} β_{1}^{- 1 / α} (s) d s = \infty .

(2)

Definition 1.

Let

E = {(ı, s) \in R^{2} : ı \geq s \geq ı_{0}} and E_{0} = {(ı, s) \in R^{2} : ı > s \geq ı_{0}} .

Let

φ_{i} \in C (E, R)

for

i = 1, 2

,

(i): $φ_{i} (ı, s) = 0$ for $ı \geq ı_{0}, φ_{i} (ı, s) > 0, (ı, s) \in E_{0};$
(ii): Let $\partial φ_{i} / \partial s$ on $E_{0}$ and there exist functions $a_{1}, a_{2} \in C^{1} ([ı_{0}, \infty), (0, \infty))$ and ${\hat{φ}}_{i} \in C (E_{0}, R)$ such that

$\frac{\partial}{\partial s} φ_{1} (ı, s) + \frac{a_{1}^{'} (s)}{a_{1} (s)} φ (ı, s) = {\hat{φ}}_{1} (ı, s) φ_{1}^{α / (α + 1)} (ı, s)$

(3)

and

$\frac{\partial}{\partial s} φ_{2} (ı, s) + \frac{a_{2}^{'} (s)}{a_{2} (s)} φ_{2} (ı, s) = {\hat{φ}}_{2} (ı, s) \sqrt{φ_{2} (ı, s)} .$

(4)

In recent years, and in context of oscillation theory, many studies have been devoted to the oscillation conditions for non-linear delay differential equations; the reader can refer to [8,9,10,11,12,13,14,15,16].

Li et al. [17] discussed oscillation criteria for the equation

\{\begin{matrix} {(α_{1} (ı) {|ζ^{‴} (ı)|}^{p - 2} ζ^{‴} (ı))}^{'} + β (ı) {|ς (ξ (ı))|}^{p - 2} ς (ξ (ı)) = 0, \\ 1 < p < \infty, ı \geq ı_{0} > 0, \end{matrix}

where

ζ (ı) : = ς (ı) + \hat{β} (ı) ς (ϱ (ı)) .

Liu et al. [18] have obtained some oscillation conditions for equation

\{\begin{matrix} {(α_{1} (ı) Φ (ζ^{(r - 1)} (ı)))}^{'} + α_{2} (x) Φ (ζ^{(r - 1)} (ı)) + β (ı) Φ (ζ (ξ (ı))) = 0, \\ Φ = {|s|}^{p - 2} s, ı \geq ı_{0} > 0, r is even . \end{matrix}

They used integral averaging technique.

Moaaz et al. [19] proved that equation

{(β_{1} (ı) {(ζ^{(r - 1)} (ı))}^{α})}^{'} + β_{3} (ı) ς^{α} (ξ (ı)) = 0,

(5)

is oscillatory if

\underset{ı \to \infty}{lim inf} \int_{ϱ^{- 1} (δ (ı))}^{ı} {(\frac{{(ϱ^{- 1} (δ (s)))}^{r - 1}}{β_{1}^{1 / α} (ϱ^{- 1} (δ (s)))})}^{α} β_{3} (s) F_{r}^{α} (ξ (s)) d s > \frac{{((r - 1)!)}^{α}}{e}

(6)

and

\underset{ı \to \infty}{lim inf} \int_{ϱ^{- 1} (ζ (ı))}^{ı} ϱ^{- 1} (ζ (s)) G_{r - 3} (s) d s > \frac{1}{e}

(7)

and used the Riccati method. The authors in [20] confirmed that (5) is oscillatory if

{(ξ^{- 1} (ı))}^{'} \geq ξ_{0} > 0, ϱ^{'} (ı) \geq ϱ_{0} > 0, ϱ^{- 1} (ξ (ı)) < ı

and

lim inf_{ı \to \infty} \int_{ϱ^{- 1} (ξ (ı))}^{ı} \frac{\hat{β_{3}} (s)}{β_{1} (s)} {(s^{r - 1})}^{α} d s > (\frac{1}{ξ_{0}} + \frac{{\hat{β}}_{0}^{α}}{ξ_{0} ϱ_{0}}) > \frac{{((r - 1)!)}^{α}}{e},

(8)

where

\hat{β_{3}} (ı) : = min \{β_{3} (ξ^{- 1} (ı)), β_{3} (ξ^{- 1} (ϱ (ı)))\}

. They used the comparison technique.

If we apply the results obtained by the authors in [19,20,21,22] to the equation

{(ς (ı) + \frac{7}{8} ς (\frac{1}{e} ı))}^{(4)} + \frac{j}{ı^{4}} ς (\frac{1}{e^{2}} ı) = 0, ı \geq 1,

(9)

then we get that (9) is oscillatory if

j > 113981.3,

j > 3561.9, j > 3008.5, j > 587.93,

respectively.

Thus, [19] improved the results in [20,21,22].

This article purpose to establish new oscillation criteria for (1). The criteria obtained in this article complement the results in [19,20,21,22]. We provided an example to examine our main results.

These are some of the important Lemmas:

Lemma 1

([3]). If

ς^{(i)} (ı) > 0,

i = 0, 1, \dots, r,

and

ς^{(r + 1)} (ı) < 0,

then

\frac{ς (ı)}{ı^{r} / r!} \geq \frac{ς^{'} (ı)}{ı^{r - 1} / (r - 1)!} .

Lemma 2

([5]). Let

ς \in C^{r} ([ı_{0}, \infty), (0, \infty)), ς^{(r - 1)} (ı) ς^{(r)} (ı) \leq 0

and

{lim}_{ı \to \infty} ς (ı) \neq 0,

then for every

ε \in (0, 1)

there exists

ı_{ε} \geq ı_{1}

such that

ς (ı) \geq \frac{ε}{(r - 1)!} ı^{r - 1} |ς^{(r - 1)} (ı)| for ı \geq ı_{ε} \geq ı_{1}, ε \in (0, 1) .

Lemma 3

([4]). Let

α \geq 1,

L_{2} > 0

. Then

L_{1} ς - L_{2} ς^{(α + 1) / α} \leq \frac{α^{α}}{{(α + 1)}^{α + 1}} \frac{L_{1}^{α + 1}}{L_{2}^{α}} .

Lemma 4

([8]). Assume that

ς b e a n e v e n t u a l l y p o s i t i v e s o l u t i o n o f (1) .

(10)

Then, we have these cases:

\begin{matrix} (S_{1}) & ζ (ı) > 0, ζ^{'} (ı) > 0, ζ^{″} (ı) > 0, ζ^{(r - 1)} (ı) > 0, ζ^{(r)} (ı) < 0, \\ (S_{2}) & ζ (ı) > 0, ζ^{(j)} (ı) > 0, ζ^{(j + 1)} (ı) < 0 f o r a l l o d d i n t e g e r \\ j \in {1, 3, \dots, r - 3}, ζ^{(r - 1)} (ı) > 0, ζ^{(r)} (ı) < 0, \end{matrix}

for

ı \geq ı_{1},

where

ı_{1} \geq ı_{0}

is sufficiently large.

Lemma 5.

Let (10) hold and

{(ϱ^{- 1} (ϱ^{- 1} (ı)))}^{r - 1} < {(ϱ^{- 1} (ı))}^{r - 1} \hat{β} (ϱ^{- 1} (ϱ^{- 1} (ı))) .

(11)

Then

ς (ı) \geq \frac{ζ (ϱ^{- 1} (ı))}{\hat{β} (ϱ^{- 1} (ı))} - \frac{1}{\hat{β} (ϱ^{- 1} (ı))} \frac{ζ (ϱ^{- 1} (ϱ^{- 1} (ı)))}{\hat{β} (ϱ^{- 1} (ϱ^{- 1} (ı)))} .

(12)

Proof.

Let (10) hold. From the definition of

ζ (ı)

, we have that

\hat{β} (ı) ς (ϱ (ı)) = ζ (ı) - ς (ı)

and so

\hat{β} (ϱ^{- 1} (ı)) ς (ı) = ζ (ϱ^{- 1} (ı)) - ζ (ϱ^{- 1} (ı)) .

Repeating the same process, we obtain

ς (ı) = \frac{1}{\hat{β} (ϱ^{- 1} (ı))} (ζ (ϱ^{- 1} (ı)) - (\frac{ζ (ϱ^{- 1} (ϱ^{- 1} (ı)))}{\hat{β} (ϱ^{- 1} (ϱ^{- 1} (ı)))} - \frac{ς (ϱ^{- 1} (ϱ^{- 1} (ı)))}{\hat{β} (ϱ^{- 1} (ϱ^{- 1} (ı)))})),

which yields

ς (ı) \geq \frac{ζ (ϱ^{- 1} (ı))}{\hat{β} (ϱ^{- 1} (ı))} - \frac{1}{\hat{β} (ϱ^{- 1} (ı))} \frac{ζ (ϱ^{- 1} (ϱ^{- 1} (ı)))}{\hat{β} (ϱ^{- 1} (ϱ^{- 1} (ı)))} .

Thus, (12) holds. This completes the proof. □

Here, we define the next notations:

\begin{matrix} F_{ı} (ı) & = & \frac{1}{\hat{β} (ϱ^{- 1} (ı))} (1 - \frac{{(ϱ^{- 1} (ϱ^{- 1} (ı)))}^{ı - 1}}{{(ϱ^{- 1} (ı))}^{ı - 1} \hat{β} (ϱ^{- 1} (ϱ^{- 1} (ı)))}), for ı = 2, r, \\ G_{0} (ı) & = & {(\frac{1}{β_{1} (ı)} \int_{ı}^{\infty} β_{3} (s) F_{2}^{α} (ξ (s)) d s)}^{1 / α}, \\ Θ (ı) & = & α \frac{ε_{1}}{(r - 2)!} {(\frac{β_{1} (ı)}{β_{1} (ϱ^{- 1} (ξ (ı)))})}^{1 / α} \frac{{(ϱ^{- 1} (ξ (ı)))}^{'} {(ϱ^{- 1} (ξ (ı)))}^{r - 2}}{{(β_{1} a_{1})}^{1 / α} (ı)}, \\ \tilde{Θ} (ı) & = & \frac{{\hat{φ}}_{1}^{α + 1} (ı, s) φ_{1}^{α} (ı, s)}{{(α + 1)}^{α + 1}} \frac{{((r - 2)!)}^{α} β_{1} (ϱ^{- 1} (ξ (ı))) a_{1} (ı)}{{(ε_{1} {(ϱ^{- 1} (ξ (ı)))}^{'} {(ϱ^{- 1} (ξ (ı)))}^{r - 2})}^{α}} \end{matrix}

and

G_{m} (ı) = \int_{ı}^{\infty} G_{m - 1} (s) d s, m = 1, 2, \dots, r - 3 .

Lemma 6.

Let (10) hold and

{(β_{1} (ı) {(ζ^{(r - 1)} (ı))}^{α})}^{'} \leq - ζ^{α} (ϱ^{- 1} (ξ (ı))) β_{3} (ı) F_{r}^{α} (ξ (ı)), i f ζ s a t i s f i e s (S_{1})

(13)

and

ζ^{″} (ı) + G_{r - 3} (ı) ζ (ϱ^{- 1} (ξ (ı))) \leq 0, i f ζ s a t i s f i e s (S_{2}) .

(14)

Proof.

Let (10) hold. From Lemma 4, we have

(S_{1})

and

(S_{2})

.

Let case

(S_{1})

holds. Using Lemma 6, we get

ζ (ı) \geq \frac{1}{(r - 1)} ı ζ^{'} (ı)

and hence the function

ı^{1 - r} ζ (ı)

is nonincreasing, which with the fact that

ϱ (ı) \leq ı

gives

{(ϱ^{- 1} (ı))}^{r - 1} ζ (ϱ^{- 1} (ϱ^{- 1} (ı))) \leq {(ϱ^{- 1} (ϱ^{- 1} (ı)))}^{r - 1} ζ (ϱ^{- 1} (ı)) .

(15)

Combining (12) and (15), we conclude that

\begin{matrix} ς (ı) & \geq & \frac{1}{\hat{β} (ϱ^{- 1} (ı))} (1 - \frac{{(ϱ^{- 1} (ϱ^{- 1} (ı)))}^{r - 1}}{{(ϱ^{- 1} (ı))}^{r - 1} \hat{β} (ϱ^{- 1} (ϱ^{- 1} (ı)))}) ζ (ϱ^{- 1} (ı)) \\ = & F_{r} (ı) ζ (ϱ^{- 1} (ı)) . \end{matrix}

(16)

From (1) and (16), we obtain

\begin{matrix} {(β_{1} (ı) {(ζ^{(r - 1)} (ı))}^{α})}^{'} & \leq & - β_{3} (ı) F_{r}^{α} (ξ (ı)) ζ^{α} (ϱ^{- 1} (ξ (ı))) \\ \leq & - ζ^{α} (ϱ^{- 1} (ξ (ı))) β_{3} (ı) F_{r}^{α} (ξ (ı)) . \end{matrix}

Thus, (13) holds.

Let case

(S_{2})

holds. Using Lemma 6, we get that

ζ (ı) \geq ı ζ^{'} (ı)

(17)

and thus the function

ı^{- 1} ζ (ı)

is nonincreasing, eventually. Since

ϱ^{- 1} (ı) \leq ϱ^{- 1} (ϱ^{- 1} (ı))

, we obtain

ϱ^{- 1} (ı) ζ (ϱ^{- 1} (ϱ^{- 1} (ı))) \leq ϱ^{- 1} (ϱ^{- 1} (ı)) ζ (ϱ^{- 1} (ı)) .

(18)

Combining (12) and (18), we find

\begin{matrix} ς (ı) & \geq & \frac{1}{\hat{β} (ϱ^{- 1} (ı))} (1 - \frac{(ϱ^{- 1} (ϱ^{- 1} (ı)))}{(ϱ^{- 1} (ı)) \hat{β} (ϱ^{- 1} (ϱ^{- 1} (ı)))}) ζ (ϱ^{- 1} (ı)) \\ = & F_{2} (ı) ζ (ϱ^{- 1} (ı)), \end{matrix}

which with (1) yields

{(β_{1} (ı) {(ζ^{(r - 1)} (ı))}^{α})}^{'} + β_{3} (ı) F_{2}^{α} (ξ (ı)) ζ^{α} (ϱ^{- 1} (ξ (ı))) \leq 0 .

(19)

Integrating the (19) from ı to ∞, we obtain

ζ^{(r - 1)} (ı) \geq G_{0} (ı) ζ (ϱ^{- 1} (ξ (ı))) .

NOW, integrating from ı to ∞ a total of

r - 3

times, we obtain

ζ^{″} (ı) + G_{r - 3} (ı) ζ (ϱ^{- 1} (ξ (ı))) \leq 0 .

Thus, (14) holds. This completes the proof. □

2. Philos-Type Oscillation Criteria

Theorem 1.

Let

ξ (ı) \leq ξ (ı)

and (11) holds. If the functions

a_{1}, a_{2} \in^{1} ([ı_{0}, \infty), R)

such that

\underset{ı \to \infty}{lim sup} \frac{1}{φ (ı, ı_{1})} \int_{ı_{1}}^{ı} (φ (ı, s) D (s) - \tilde{Θ} (s)) d s = \infty

(20)

and

\underset{ı \to \infty}{lim sup} \frac{1}{φ_{2} (ı, ı_{1})} \int_{ı_{1}}^{ı} (φ_{2} (ı, s) D^{*} (s) - \frac{a_{2} (s) {\hat{φ}}_{2}^{2} (ı, s)}{4}) d s = \infty,

(21)

where

D (s) = a_{1} (ı) β_{3} (ı) F_{r}^{α} (ξ (ı)), D^{*} (s) = a_{2} (ı) G_{r - 3} (ı) (\frac{ϱ^{- 1} (ξ (ı))}{ı})

and

\tilde{Θ} (s) = \frac{{\hat{φ}}_{1}^{α + 1} (ı, s) φ_{1}^{α} (ı, s)}{{(α + 1)}^{α + 1}} \frac{{((r - 2)!)}^{α} β_{1} (ϱ^{- 1} (ξ (ı))) a_{1} (ı)}{{(ε_{1} {(ϱ^{- 1} (ξ (ı)))}^{'} {(ϱ^{- 1} (ξ (ı)))}^{r - 2})}^{α}},

then (1) is oscillatory.

Proof.

Let

ς

be a non-oscillatory solution of (1), then

ς > 0 .

Let

(S_{1})

holds.

Define

X (ı) : = a_{1} (ı) \frac{β_{1} (ı) {(ζ^{(r - 1)} (ı))}^{α}}{ζ^{α} (ϱ^{- 1} (ξ (ı)))} > 0 .

Differentiating and using (13), we obtain

\begin{matrix} X^{'} (ı) & \leq & \frac{a_{1}^{'} (ı)}{a_{1} (ı)} X (ı) - a_{1} (ı) β_{3} (ı) F_{r}^{α} (ξ (ı)) \\ - α a_{1} (ı) \frac{β_{1} (ı) {(ζ^{(r - 1)} (ı))}^{α} {(ϱ^{- 1} (ξ (ı)))}^{'} ζ_{u}^{'} (ϱ^{- 1} (ξ (ı)))}{ζ_{u}^{α + 1} (ϱ^{- 1} (ξ (ı)))} . \end{matrix}

(22)

Recalling that

β_{1} (ı) {(ζ^{(r - 1)} (ı))}^{α}

is decreasing, we get

β_{1} (ϱ^{- 1} (ξ (ı))) {(ζ^{(r - 1)} (ϱ^{- 1} (ξ (ı))))}^{α} \geq β_{1} (ı) {(ζ^{(r - 1)} (ı))}^{α} .

This yields

{(ζ^{(r - 1)} (ϱ^{- 1} (ξ (ı))))}^{α} \geq \frac{β_{1} (ı)}{β_{1} (ϱ^{- 1} (ξ (ı)))} {(ζ^{(r - 1)} (ı))}^{α} .

(23)

It follows from Lemma 2 that

ζ^{'} (ϱ^{- 1} (ξ (ı))) \geq \frac{ε_{1}}{(r - 2)!} {(ϱ^{- 1} (ξ (ı)))}^{r - 2} ζ^{(r - 1)} (ϱ^{- 1} (ξ (ı))),

(24)

for all

ε_{1} \in (0, 1)

and every sufficiently large ı. Thus, by (22)–(24), we get

\begin{matrix} X^{'} (ı) \leq \frac{a_{1}^{'} (ı)}{a_{1} (ı)} X (ı) - a_{1} (ı) β_{3} (ı) F_{r}^{α} (ξ (ı)) \\ - α a_{1} (ı) \frac{ε_{1}}{(r - 2)!} {(\frac{β 1 (ı)}{β 1 (ϱ^{- 1} (ξ (ı)))})}^{1 / α} \frac{β_{1} (ı) {(ζ^{(r - 1)} (ı))}^{α + 1} {(ϱ^{- 1} (ξ (ı)))}^{'} {(ϱ^{- 1} (ξ (ı)))}^{r - 2}}{ζ^{α + 1} (ϱ^{- 1} (ξ (ı)))} . \end{matrix}

Hence,

\begin{matrix} X^{'} (ı) & \leq & \frac{a_{1}^{'} (ı)}{a_{1} (ı)} X (ı) - a_{1} (ı) β_{3} (ı) F_{r}^{α} (ξ (ı)) \\ - Θ (ı) X^{\frac{α + 1}{α}} (ı) . \end{matrix}

(25)

Multiplying (25) by

φ (ı, s)

and integrating from

ı_{1}

to ı; we obtain

\begin{matrix} \int_{ı_{1}}^{ı} φ (ı, s) D (s) d s & \leq & X (ı_{1}) φ (ı, ı_{1}) + \int_{ı_{1}}^{ı} (\frac{\partial}{\partial s} φ (ı, s) + \frac{a_{1}^{'} (s)}{a_{1} (s)} φ (ı, s)) X (s) d s \\ - \int_{ı_{1}}^{ı} Θ (s) φ (ı, s) X^{\frac{α + 1}{α}} (s) d s . \end{matrix}

From (3), we get

\begin{matrix} \int_{ı_{1}}^{ı} φ (ı, s) D (s) d s & \leq & X (ı_{1}) φ (ı, ı_{1}) + \int_{ı_{1}}^{ı} {\hat{φ}}_{1} (ı, s) φ_{1}^{α / (α + 1)} (ı, s) X (s) d s \\ - \int_{ı_{1}}^{ı} Θ (s) φ (ı, s) X^{\frac{α + 1}{α}} (s) d s . \end{matrix}

(26)

Using Lemma 3 with

L_{2} = Θ (s) φ (ı, s), L_{1} = {\hat{φ}}_{1} (ı, s) φ_{1}^{α / (α + 1)} (ı, s)

and

ς = X (s)

, we get

\begin{matrix} {\hat{φ}}_{1} (ı, s) φ_{1}^{α / (α + 1)} (ı, s) X (s) - Θ (s) φ (ı, s) X^{\frac{α + 1}{α}} (s) \\ \leq & \frac{{\hat{φ}}_{1}^{α + 1} (ı, s) φ_{1}^{α} (ı, s)}{{(α + 1)}^{α + 1}} \frac{{((r - 2)!)}^{α} β_{1} (ϱ^{- 1} (ξ (ı))) a_{1} (ı)}{{(ε_{1} {(ϱ^{- 1} (ξ (ı)))}^{'} {(ϱ^{- 1} (ξ (ı)))}^{r - 2})}^{α}}, \end{matrix}

which, with (26) gives

\frac{1}{φ (ı, ı_{1})} \int_{ı_{1}}^{ı} (φ (ı, s) D (s) - \tilde{Θ} (s)) d s \leq X (ı_{1}),

which contradicts (20).

Let

(S_{2})

holds. Define

Z (ı) = a_{2} (ı) \frac{ζ^{'} (ı)}{ζ (ı)} .

(27)

Then

Z (ı) > 0

for

ı \geq ı_{1}

. By differentiating Z and using (14), we find

\begin{matrix} Z^{'} (ı) & = & \frac{a_{2}^{'} (ı)}{a_{2} (ı)} Z (ı) + a_{2} (ı) \frac{ζ^{″} (ı)}{ζ (ı)} - a_{2} (ı) {(\frac{ζ^{'} (ı)}{ζ (ı)})}^{2} \\ \leq & \frac{a_{2}^{'} (ı)}{a_{2} (ı)} Z (ı) - a_{2} (ı) G_{r - 3} (ı) \frac{ζ (ϱ^{- 1} (ξ (ı)))}{ζ (ı)} - \frac{1}{a_{2} (ı)} Z^{2} (ı) . \end{matrix}

(28)

By using Lemma 1, we find that

ζ (ı) \geq ı ζ^{'} (ı) .

(29)

From (29), we get that

ζ (ϱ^{- 1} (ξ (ı))) \geq \frac{ϱ^{- 1} (ξ (ı))}{ı} ζ (ı) .

(30)

Thus, from (28) and (30), we obtain

Z^{'} (ı) \leq \frac{a_{2}^{'} (ı)}{a_{2} (ı)} Z (ı) - a_{2} (ı) G_{r - 3} (ı) (\frac{ϱ^{- 1} (ξ (ı))}{ı}) - \frac{1}{a_{2} (ı)} Z^{2} (ı) .

(31)

Multiplying (31) by

φ_{2} (ı, s)

and integrating the resulting from

ı_{1}

to ı, we see

\begin{matrix} \int_{ı_{1}}^{ı} φ_{2} (ı, s) D^{*} (s) d s & \leq & Z (ı_{1}) φ_{2} (ı, ı_{1}) \\ + \int_{ı_{1}}^{ı} (\frac{\partial}{\partial s} φ_{2} (ı, s) + \frac{a_{2}^{'} (s)}{a_{2} (s)} φ_{2} (ı, s)) Z (s) d s \\ - \int_{ı_{1}}^{ı} \frac{1}{a_{2} (s)} φ_{2} (ı, s) Z^{2} (s) d s . \end{matrix}

Thus,

\begin{matrix} \int_{ı_{1}}^{ı} φ_{2} (ı, s) D^{*} (s) d s & \leq & Z (ı_{1}) φ_{2} (ı, ı_{1}) + \int_{ı_{1}}^{ı} {\hat{φ}}_{2} (ı, s) \sqrt{φ_{2} (ı, s)} Z (s) d s \\ - \int_{ı_{1}}^{ı} \frac{1}{a_{2} (s)} φ_{2} (ı, s) Z^{2} (s) d s \\ \leq & Z (ı_{1}) φ_{2} (ı, ı_{1}) + \int_{ı_{1}}^{ı} \frac{a_{2} (s) {\hat{φ}}_{2}^{2} (ı, s)}{4} d s \end{matrix}

and so

\frac{1}{φ_{2} (ı, ı_{1})} \int_{ı_{1}}^{ı} (φ_{2} (ı, s) D^{*} (s) - \frac{a_{2} (s) {\hat{φ}}_{2}^{2} (ı, s)}{4}) d s \leq Z (ı_{1}),

which contradicts (21). This completes the proof. □

Corollary 1.

Let (11) holds and

a_{1}, a_{2} \in^{1} ([ı_{0}, \infty), R)

such that

\int_{ı_{0}}^{\infty} (ϖ (s) - \frac{(r - 2)!^{α}}{{(α + 1)}^{α + 1}} \frac{β_{1} (ϱ^{- 1} (ξ (ı))) {(a_{1}^{'} (ı))}^{α + 1}}{{(ε_{1} a_{1} (ı) {(ϱ^{- 1} (ξ (ı)))}^{'} {(ϱ^{- 1} (ξ (ı)))}^{r - 2})}^{α}}) d s = \infty

(32)

and

\int_{ı_{0}}^{\infty} (θ (s) - \frac{{(a_{2}^{'} (s))}^{2}}{4 a_{2} (s)}) d s = \infty,

(33)

for some

ε_{1} \in (0, 1)

, where

ϖ (ı) : = a_{1} (ı) β_{3} (ı) F_{r}^{α} (ξ (ı))

and

θ (ı) : = F_{1} a_{2} (ı) \int_{ı}^{\infty} {(\frac{1}{β_{1} (ϱ)} \int_{ϱ}^{\infty} β_{3} (s) {(\frac{ϱ^{- 1} (ξ (s))}{s})}^{α} d s)}^{1 / α} d ϱ,

then (1) is oscillatory.

Proof.

The proof of this theorem is the same as that of Theorem 1. □

Example 1.

Consider the equation

{(ς (ı) + {\hat{β}}_{0} ς (δ ı))}^{(r)} + \frac{j}{ı^{r}} ς (λ ı) = 0,

(34)

where

ı \geq 1, j > 0,

δ \in ({\hat{β}}_{0}^{- 1 / (r - 1)}, 1),

λ \in (0, δ),

β_{1} (ı) = 1,

\hat{β} (ı) = {\hat{β}}_{0},

ϱ (ı) = δ ı, ξ (ı) = λ ı

and

β_{3} (ı) = j / ı^{r}

. Thus, we find

F_{1} (ı) = \frac{1}{{\hat{β}}_{0}} (1 - \frac{1}{δ^{3} {\hat{β}}_{0}}), F_{2} (ı) = \frac{1}{{\hat{β}}_{0}} (1 - \frac{1}{δ {\hat{β}}_{0}}), Ψ (ı) = \frac{F_{1} j}{ı}

and

B (ı) = \frac{F_{2} λ j}{6 δ ı} .

Thus, (32) and (33) becomes

\int_{ı_{0}}^{\infty} (\frac{F_{1} (ı) j}{s} - \frac{9 δ^{4}}{2 λ^{4}} \frac{1}{s}) d s = (F_{1} (ı) j - \frac{9 δ^{4}}{2 λ^{4}}) (+ \infty)

and

\int_{ı_{0}}^{\infty} (B (s) - \frac{{(a_{2}^{'} (s))}^{2}}{4 a_{2} (s)}) d s = (\frac{F_{2} λ}{6 δ} j - \frac{1}{4}) (+ \infty),

From Corollary 1, the Equation (34) is oscillatory if

j \frac{1}{{\hat{β}}_{0}} (1 - \frac{1}{δ^{3} {\hat{β}}_{0}}) > \frac{9 δ^{4}}{2 λ^{4}}

(35)

and

j \frac{1}{{\hat{β}}_{0}} (1 - \frac{1}{δ {\hat{β}}_{0}}) > \frac{3 δ}{2 λ} .

(36)

Let

{\hat{β}}_{0} = 16,

δ = 1 / 2

and

λ = 1 / 3

, Condition (35) yields

j > 41.14

. Whereas, the criterion obtained from the results of [20] is

j > 4850.4

and [19] is

j > 587.93 .

Remark 1.

Hence, our results extend and simplify the results in [19,20,21,22].

Example 2.

Consider the equation

{(ς (ı) + \frac{1}{3} ς (\frac{ı}{2}))}^{(4)} + \frac{j}{ı^{4}} ξ (\frac{ı}{2}) = 0,

(37)

where

ı \geq 1

and

q_{0} > 0 .

Let

r = 4, β_{1} (ı) = 1, \hat{β} (ı) = 1 / 3, ϱ (ı) = ξ (ı) = ı / 2 and β_{3} (ı) = j / ı^{4} .

Then

\int_{ı_{0}}^{\infty} β_{1}^{- 1 / α} (s) d s = \infty .

So, we see that the conditions (20) and (21) holds. By Theorem 1, all solution of (37) is oscillatory.

3. Conclusions

In this article, we give several oscillatory properties of differential equation of even-order with neutral term. The criteria obtained in this article complements the results in [19,20,21,22]. In our future work, and to supplement our results, we will present and discuss some oscillation theorems for differential equations of this type by using comparing technique with first/second-order delay differential equation.

Author Contributions

Conceptualization, F.A., O.B., T.A.N., K.M.K. and Y.N.R. These authors contributed equally to this work. All authors have read and agreed to the published version of the manuscript.

Funding

This research work was supported by the Deanship of Scientific Research at King Khalid University under Grant number RGP. 1/372/42 also the Deanship of Scientific Research at Majmaah University under Project Number No: R-2021-43, and the Deanship of Scientific Research at Taif University under Project Number TURSP-2020/031.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Acknowledgments

The authors thank the reviewers for their useful comments, which led to the improvement of the content of the paper. Khaled Mohamed Khedher would like to thank the Deanship of Scientific Research at King Khalid University for funding this work through the large research groups under grant number RGP.1/372/42. Fahad Alsharari would like to thank Deanship of Scientific Research at Majmaah University for supporting this work under Project Number No: R-2021-43. (Taher A. Nofal) Taif University Researchers Supporting Project number (TURSP-2020/031), Taif University, Taif, Saudi Arabia.

Conflicts of Interest

The authors declare no conflict of interest.

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Alsharari, F.; Bazighifan, O.; Nofal, T.A.; Khedher, K.M.; Raffoul, Y.N. Oscillatory Solutions to Neutral Delay Differential Equations. Mathematics 2021, 9, 714. https://doi.org/10.3390/math9070714

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Alsharari F, Bazighifan O, Nofal TA, Khedher KM, Raffoul YN. Oscillatory Solutions to Neutral Delay Differential Equations. Mathematics. 2021; 9(7):714. https://doi.org/10.3390/math9070714

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Alsharari, Fahad, Omar Bazighifan, Taher A. Nofal, Khaled Mohamed Khedher, and Youssef N. Raffoul. 2021. "Oscillatory Solutions to Neutral Delay Differential Equations" Mathematics 9, no. 7: 714. https://doi.org/10.3390/math9070714

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Oscillatory Solutions to Neutral Delay Differential Equations

Abstract

1. Introduction

2. Philos-Type Oscillation Criteria

3. Conclusions

Author Contributions

Funding

Institutional Review Board Statement

Informed Consent Statement

Data Availability Statement

Acknowledgments

Conflicts of Interest

References

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