Oscillatory Behavior of Fourth-Order Differential Equations with Neutral Delay

Moaaz, Osama; El-Nabulsi, Rami Ahmad; Bazighifan, Omar

doi:10.3390/sym12030371

Open AccessArticle

Oscillatory Behavior of Fourth-Order Differential Equations with Neutral Delay

by

Osama Moaaz

^1,†

,

Rami Ahmad El-Nabulsi

^2,*,† and

Omar Bazighifan

^3,†

¹

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

²

Athens Institute for Education and Research, Mathematics and Physics Divisions, 10671 Athens, Greece

³

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

^*

Author to whom correspondence should be addressed.

^†

These authors contributed equally to this work.

Symmetry 2020, 12(3), 371; https://doi.org/10.3390/sym12030371

Submission received: 14 January 2020 / Revised: 5 February 2020 / Accepted: 10 February 2020 / Published: 2 March 2020

(This article belongs to the Special Issue Non-Standard Lagrangians and Hamiltonians in Theoretical Physics and Applied Mathematics)

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Abstract

:

In this paper, new sufficient conditions for oscillation of fourth-order neutral differential equations are established. One objective of our paper is to further improve and complement some well-known results which were published recently in the literature. Symmetry ideas are often invisible in these studies, but they help us decide the right way to study them, and to show us the correct direction for future developments. An example is given to illustrate the importance of our results.

Keywords:

fourth-order differential equations; neutral delay; oscillation

1. Introduction

Consider the fourth-order neutral differential equation of the form

{(r (t) {(N_{u}^{' ″} (t))}^{α})}^{'} + q (t) u^{β} (σ (t)) = 0,

(1)

where

t \geq t_{0}

and

N_{u} (t) : = u (t) + c (t) u (τ (t))

. In this paper, we assume that

H1:: $α$ and $β$ are quotients of odd positive integers and $β \geq α;$
H2:: $r \in C^{1} ([t_{0}, \infty)),$ $r (t) > 0,$ $r^{'} (t) \geq 0$ and $\int^{\infty} r^{- 1 / α} (s) d s = \infty;$
H3:: $c, q \in C ([t_{0}, \infty)),$ $q (t) > 0,$ $0 \leq c (t) < c_{0} < \infty$ and $q (t)$ is not identically zero for large t;
H4:: $τ \in C^{1} ([t_{0}, \infty)), σ \in C ([t_{0}, \infty)),$ $τ^{'} (t) > 0,$ $τ (t) \leq t$ and ${lim}_{t \to \infty} τ (t) = {lim}_{t \to \infty} σ (t) = \infty .$

By a solution of (1), we mean a function u

\in C^{3} ([t_{y}, \infty)), t_{y} \geq t_{0},

which has the property

r (t) {(N_{u}^{' ″} (t))}^{α} \in C^{1} ([t_{y}, \infty)),

and satisfies (1) on

[t_{y}, \infty)

. We consider only those solutions u of (1) which satisfy

sup {|u (t)| : t \geq T} > 0,

for all

T \geq t_{y}

. A solution u of (1) is said to be non-oscillatory if it is positive or negative, ultimately; otherwise, it is said to be oscillatory.

The qualitative study of the neutral delay differential equations has, besides its theoretical interest, significant practical importance, see [1]. Lately, there has been a lot of research activities concerning the oscillation of differential equations with a different order, see [1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24].

Next, we quickly audit some significant oscillation criteria got for higher-order equations which can be viewed as an inspiration for this paper.

Theorem 1

(A. [23] (Theorem 2)). Every solution u of

N_{u}^{(n)} (t) + q (t) u (σ (t)) = 0

(2)

is oscillatory, if

\underset{t \to \infty}{lim inf} \int_{σ (t)}^{t} Q (s) d s > \frac{(n - 1) 2^{(n - 1) (n - 2)}}{e}

(3)

or

\underset{t \to \infty}{lim sup} \int_{σ (t)}^{t} Q (s) d s > (n - 1) 2^{(n - 1) (n - 2)}, σ^{'} (t) \geq 0,

where

Q (t) : = σ^{n - 1} (t) (1 - c (σ (t))) q (t)

.

Theorem 2

(B. [24] (Corollary 1)). If either

lim inf_{t \to \infty} \int_{σ (t)}^{t} Q (s) d s > \frac{(n - 1)!}{e}

(4)

or

lim sup_{t \to \infty} \int_{σ (t)}^{t} Q (s) d s > (n - 1)!, σ (t) \geq 0

holds, then (2) is oscillatory.

Theorem 3

(C. [22] (Corollary 2.16)). Equation (1) is oscillatory if

{(σ^{- 1} (t))}^{'} \geq σ_{0} > 0, τ^{'} (t) \geq τ_{0} > 0, τ^{- 1} (σ (t)) < t

and

lim inf_{t \to \infty} \int_{τ^{- 1} (σ (t))}^{t} \frac{\hat{q} (s)}{r (s)} {(s^{n - 1})}^{α} d s > (\frac{1}{σ_{0}} + \frac{c_{0}^{α}}{σ_{0} τ_{0}}) \frac{{((n - 1)!)}^{α}}{e},

(5)

where

\hat{q} (t) : = min \{q (σ^{- 1} (t)), q (σ^{- 1} (τ (t)))\}

.

It’s easy to see that results in [24] improved results of [23], where

(n - 1)! < (n - 1) 2^{(n - 1) (n - 2)}

for

n > 3

. Using a different comparison approach Xing et al. [22], improved the results of [23,24].

In this paper, we obtain new oscillation criteria for fourth-order differential Equation (1) with neutral delay by using the Riccati transformations. Our results improve the results in [22,23,24]. An example is given to illustrate the importance of our results.

2. Main Results

Here, we consider the following notations:

c_{1} (t) = \frac{1}{c (τ^{- 1} (t))} (1 - \frac{{(τ^{- 1} (τ^{- 1} (t)))}^{3}}{{(τ^{- 1} (t))}^{3} c (τ^{- 1} (τ^{- 1} (t)))})

and

c_{2} (t) = \frac{1}{c (τ^{- 1} (t))} (1 - \frac{(τ^{- 1} (τ^{- 1} (t)))}{(τ^{- 1} (t)) c (τ^{- 1} (τ^{- 1} (t)))}) .

All functional inequalities are assumed to hold eventually, that is, they are assumed to be satisfied for all t sufficiently large. We begin with the following auxiliary lemmas that can be found in [3,4,15], respectively.

Lemma 1.

Assume that

u, v \geq 0

and β is a positive real number. Then

{(u + v)}^{β} \leq 2^{β - 1} (u^{β} + v^{β}), for β \geq 1

and

{(u + v)}^{β} \leq u^{β} + v^{β}, for β \leq 1 .

Lemma 2.

If the function u satisfies

u^{(i)} (t) > 0,

i = 0, 1, \dots, n,

and

u^{(n + 1)} (t) < 0,

then

\frac{u (t)}{t^{N} / n!} \geq \frac{u^{'} (t)}{t^{n - 1} / (n - 1)!} .

Lemma 3.

Let

u \in C^{n} ([t_{0}, \infty), (0, \infty)) .

Assume that

u^{(n)} (t)

is of fixed sign and not identically zero on

[t_{0}, \infty)

and that there exists a

t_{1} \geq t_{0}

such that

u^{(n - 1)} (t) u^{(n)} (t) \leq 0

for all

t \geq t_{1}

. If

{lim}_{t \to \infty} u (t) \neq 0,

then for every

μ \in (0, 1)

there exists

t_{μ} \geq t_{1}

such that

u (t) \geq \frac{μ}{(n - 1)!} t^{n - 1} |u^{(n - 1)} (t)| for t \geq t_{μ} .

At studying the asymptotic properties of the positive solutions of (1), it is easy to verify—by [3] (Lemma 2.2.1)—that the function

N_{u}

has the following two possible cases:

Lemma 4.

Assume that

u

is an eventually positive solution of (1). Then, there exist two possible cases:

\begin{matrix} (S_{1}) N_{u}^{(κ)} (t) & > & 0 f o r κ = 0, 1, 2, 3, \\ (S_{2}) N_{u}^{(κ)} (t) & > & 0 f o r κ = 0, 1, 3, a n d N_{u}^{″} (u) < 0, \end{matrix}

for

t \geq t_{1},

where

t_{1} \geq t_{0}

is sufficiently large.

Lemma 5.

If

u

is an eventually positive solution of (1) and

{(τ^{- 1} (τ^{- 1} (t)))}^{3} < {(τ^{- 1} (t))}^{3} c (τ^{- 1} (τ^{- 1} (t))),

(6)

then

u (t) \geq \frac{1}{c (τ^{- 1} (t))} (N_{u} (τ^{- 1} (t)) - \frac{1}{c (τ^{- 1} (τ^{- 1} (t)))} N_{u} (τ^{- 1} (τ^{- 1} (t)))) .

(7)

Moreover,

{(r (t) {(N_{u}^{' ″} (t))}^{α})}^{'} \leq - q (t) c_{1}^{β} (σ (t)) N_{u}^{β} (τ^{- 1} (σ (t))), if N_{u} satisfies (S_{1})

(8)

and

N_{u}^{″} (t) \leq - c_{N}^{β / α} N_{u}^{β / α} (t) \int_{t}^{\infty} {(\frac{1}{r (ϱ)} \int_{ϱ}^{\infty} q (s) {(\frac{τ^{- 1} (σ (s))}{s})}^{β} d s)}^{1 / α} d ϱ, if N_{u} satisfies (S_{2}) .

(9)

Proof.

Let u be an eventually positive solution of (1) on

[t_{0}, \infty)

. From the definition of

N_{u} (t)

, we see that

c (t) u (τ (t)) = N_{u} (t) - u (t)

and so

c (τ^{- 1} (t)) u (t) = N_{u} (τ^{- 1} (t)) - u (τ^{- 1} (t)) .

Repeating the same process, we obtain

u (t) = \frac{1}{c (τ^{- 1} (t))} (N_{u} (τ^{- 1} (t)) - (\frac{N_{u} (τ^{- 1} (τ^{- 1} (t)))}{c (τ^{- 1} (τ^{- 1} (t)))} - \frac{u (τ^{- 1} (τ^{- 1} (t)))}{c (τ^{- 1} (τ^{- 1} (t)))})),

which yields

u (t) \geq \frac{N_{u} (τ^{- 1} (t))}{c (τ^{- 1} (t))} - \frac{1}{c (τ^{- 1} (t))} \frac{N_{u} (τ^{- 1} (τ^{- 1} (t)))}{c (τ^{- 1} (τ^{- 1} (t)))} .

Thus, (7) holds.

Next, it follows from Lemma 4 that there exist two possible cases

(S_{1})

and

(S_{2})

.

Let

(S_{1})

holds. Using Lemma 2, we get

N_{u} (t) \geq \frac{1}{3} t N_{u}^{'} (t)

and hence the function

t^{- 3} N_{u} (t)

is nonincreasing, which with the fact that

τ^{- 1} (t) \leq τ^{- 1} (τ^{- 1} (t))

gives

{(τ^{- 1} (t))}^{3} N_{u} (τ^{- 1} (τ^{- 1} (t))) \leq {(τ^{- 1} (τ^{- 1} (t)))}^{3} N_{u} (τ^{- 1} (t)) .

(10)

From (7) and (10), we get that

\begin{matrix} u (t) & \geq & \frac{N_{u} (τ^{- 1} (t))}{c (τ^{- 1} (t))} (1 - \frac{{(τ^{- 1} (τ^{- 1} (t)))}^{3}}{{(τ^{- 1} (t))}^{3} c (τ^{- 1} (τ^{- 1} (t)))}) \\ \geq & c_{1} (t) N_{u} (τ^{- 1} (t)) . \end{matrix}

(11)

From (1) and (11), we obtain

{(r (t) {(N_{u}^{' ″} (t))}^{α})}^{'} + q (t) c_{1}^{β} (σ (t)) N_{u}^{β} (τ^{- 1} (σ (t))) \leq 0 .

Thus, (8) holds.

In the case where

(S_{2})

satisfies, by using Lemma 2, we find that

N_{u} (t) \geq t N_{u}^{'} (t)

(12)

and hence

{(t^{- 1} N_{u} (t))}^{'} \leq 0

. Therefore,

τ^{- 1} (t) N_{u} (τ^{- 1} (τ^{- 1} (t))) \leq τ^{- 1} (τ^{- 1} (t)) N_{u} (τ^{- 1} (t)) .

(13)

From (7) and (13), we have

\begin{matrix} u (t) & \geq & \frac{1}{c (τ^{- 1} (t))} (1 - \frac{(τ^{- 1} (τ^{- 1} (t)))}{(τ^{- 1} (t)) c (τ^{- 1} (τ^{- 1} (t)))}) N_{u} (τ^{- 1} (t)) \\ = & c_{2} (t) N_{u} (τ^{- 1} (t)), \end{matrix}

which with (1) gives

{(r (t) {(N_{u}^{' ″} (t))}^{α})}^{'} \leq - q (t) c_{2}^{β} (σ (t)) N_{u}^{β} (τ^{- 1} (σ (t))) .

Integrating this inequality from t to

ϱ

, we obtain

r (ϱ) {(N_{u}^{' ″} (ϱ))}^{α} - r (t) {(N_{u}^{' ″} (t))}^{α} \leq - \int_{t}^{ϱ} q (t) c_{2}^{β} (σ (t)) N_{u}^{β} (τ^{- 1} (σ (t))) d s .

(14)

From (12), we get that

N_{u} (τ^{- 1} (σ (t))) \geq \frac{τ^{- 1} (σ (t))}{t} N_{u} (t) .

(15)

Letting

ϱ \to \infty

in (14) and using (15), we obtain

r (t) {(N_{u}^{' ″} (t))}^{α} \geq c_{2}^{β} (σ (t)) N_{u}^{β} (t) \int_{t}^{\infty} q (s) {(\frac{τ^{- 1} (σ (s))}{s})}^{β} d s .

Integrating this inequality again from t to ∞, we get

N_{u}^{″} (t) \leq - c_{2}^{β / α} N_{u}^{β / α} (t) \int_{t}^{\infty} {(\frac{1}{r (ϱ)} \int_{ϱ}^{\infty} q (s) {(\frac{τ^{- 1} (σ (s))}{s})}^{β} d s)}^{1 / α} d ϱ,

for all

μ_{2} \in (0, 1)

. This completes the proof. □

Theorem 4.

Let

σ (t) \leq τ (t)

and (6) hold. If there exist positive functions

θ, ρ \in C^{1} ([t_{0}, \infty))

such that

\int_{t_{0}}^{\infty} (Ψ (s) - \frac{2^{α}}{{(α + 1)}^{α + 1}} \frac{r (τ^{- 1} (σ (t))) {(θ^{'} (t))}^{α + 1}}{{(μ_{1} θ (t) {(τ^{- 1} (σ (t)))}^{'} {(σ (t))}^{'} {(τ^{- 1} (σ (t)))}^{2})}^{α}}) d s = \infty

(16)

and

\int_{t_{0}}^{\infty} (Φ (s) - \frac{{(ρ^{'} (s))}^{2}}{4 ρ (s)}) d s = \infty,

(17)

for some

μ_{1} \in (0, 1)

and every

M_{1}, M_{2} > 0

, where

Ψ (t) : = M_{1}^{β - α} θ (t) q (t) c_{1}^{β} (σ (t))

and

Φ (t) : = c_{2}^{β / α} ρ (t) M_{2}^{(β - α) / α} \int_{t}^{\infty} {(\frac{1}{r (ϱ)} \int_{ϱ}^{\infty} q (s) {(\frac{τ^{- 1} (σ (s))}{s})}^{β} d s)}^{1 / α} d ϱ,

then (1) is oscillatory.

Proof.

Let u be a non-oscillatory solution of (1) on

[t_{0}, \infty)

. Without loss of generality, we can assume that

u

is eventually positive. It follows from Lemma 4 that there exist two possible cases

(S_{1})

and

(S_{2})

. Let

(S_{1})

holds. From Lemma 5, we arrive at (8). Next, we define a function

ω

by

ω (t) : = θ (t) \frac{r (t) {(N_{u}^{' ″} (t))}^{α}}{N_{u}^{α} (τ^{- 1} (σ (t)))} > 0 .

Differentiating and using (8), we obtain

\begin{matrix} ω^{'} (t) & \leq & \frac{θ^{'} (t)}{θ (t)} ω (t) - θ (t) q (t) c_{1}^{β} (σ (t)) N_{u}^{β - α} (τ^{- 1} (σ (t))) \\ - α θ (t) \frac{r (t) {(N_{u}^{' ″} (t))}^{α} {(τ^{- 1} (σ (t)))}^{'} {(σ (t))}^{'} N_{u}^{'} (τ^{- 1} (σ (t)))}{N_{u}^{α + 1} (τ^{- 1} (σ (t)))} . \end{matrix}

(18)

Recalling that

r (t) {(N_{u}^{' ″} (t))}^{α}

is decreasing, we get

r (τ^{- 1} (σ (t))) {(N_{u}^{' ″} (τ^{- 1} (σ (t))))}^{α} \geq r (t) {(N_{u}^{' ″} (t))}^{α} .

This yields

{(N_{u}^{' ″} (τ^{- 1} (σ (t))))}^{α} \geq \frac{r (t)}{r (τ^{- 1} (σ (t)))} {(N_{u}^{' ″} (t))}^{α} .

(19)

It follows from Lemma 3 that

N_{u}^{'} (τ^{- 1} (σ (t))) \geq \frac{μ_{1}}{2} {(τ^{- 1} (σ (t)))}^{2} N_{u}^{' ″} (τ^{- 1} (σ (t))),

(20)

for all

μ_{1} \in (0, 1)

and every sufficiently large t. Thus, by (18)–(20), we get

\begin{matrix} ω^{'} (t) & \leq & \frac{θ^{'} (t)}{θ (t)} ω (t) - θ (t) q (t) c_{N}^{β} (σ (t)) N_{u}^{β - α} (τ^{- 1} (σ (t))) \\ - α θ (t) \frac{μ_{1}}{2} {(\frac{r (t)}{r (τ^{- 1} (σ (t)))})}^{1 / α} \frac{r (t) {(N_{u}^{' ″} (t))}^{α + 1} {(τ^{- 1} (σ (t)))}^{'} {(σ (t))}^{'} {(τ^{- 1} (σ (t)))}^{2}}{N_{u}^{α + 1} (τ^{- 1} (σ (t)))} . \end{matrix}

Hence,

\begin{matrix} ω^{'} (t) & \leq & \frac{θ^{'} (t)}{θ (t)} ω (t) - θ (t) q (t) c_{N}^{β} (σ (t)) N_{u}^{β - α} (τ^{- 1} (σ (t))) \\ - α \frac{μ_{1}}{2} {(\frac{r (t)}{r (τ^{- 1} (σ (t)))})}^{1 / α} \frac{{(τ^{- 1} (σ (t)))}^{'} {(σ (t))}^{'} {(τ^{- 1} (σ (t)))}^{2}}{{(r θ)}^{1 / α} (t)} ω^{\frac{α + 1}{α}} (t) . \end{matrix}

Since

N_{u}^{'} (t) > 0

, there exist a

t_{2} \geq t_{1}

and a constant

M > 0

such that

N_{u} (t) > M,

(21)

for all

t \geq t_{2}

. Using the inequality

U w - V w^{(β + 1) / β} \leq \frac{β^{β}}{{(β + 1)}^{β + 1}} \frac{U^{β + 1}}{V^{β}}, V > 0,

with

U = \frac{θ^{'} (t)}{θ (t)}, V = α \frac{μ_{1}}{2} {(\frac{r (t)}{r (τ^{- 1} (σ (t)))})}^{1 / α} \frac{{(τ^{- 1} (σ (t)))}^{'} {(σ (t))}^{'} {(τ^{- 1} (σ (t)))}^{2}}{{(r θ)}^{1 / α} (t)}

and

w = ω

, we get

ω^{'} (t) \leq - Ψ (t) + \frac{2^{α}}{{(α + 1)}^{α + 1}} \frac{r (τ^{- 1} (σ (t))) {(θ^{'} (t))}^{α + 1}}{{(μ_{1} θ (t) {(τ^{- 1} (σ (t)))}^{'} {(σ (t))}^{'} {(τ^{- 1} (σ (t)))}^{2})}^{α}} .

This implies that

\int_{t_{1}}^{t} (Ψ (s) - \frac{2^{α}}{{(α + 1)}^{α + 1}} \frac{r (τ^{- 1} (σ (t))) {(θ^{'} (t))}^{α + 1}}{{(μ_{1} θ (t) {(τ^{- 1} (σ (t)))}^{'} {(σ (t))}^{'} {(τ^{- 1} (σ (t)))}^{2})}^{α}}) d s \leq ω (t_{1}),

which contradicts (16).

On the other hand, let

(S_{2})

holds. Using Lemma 5, we get that (9) holds. Now, we define

w (t) = ρ (t) \frac{N_{u}^{'} (t)}{N_{u} (t)} .

Then

w (t) > 0

for

t \geq t_{1}

. By differentiating w and using (9), we find

\begin{matrix} w^{'} (t) & = & \frac{ρ^{'} (t)}{ρ (t)} w (t) + ρ (t) \frac{N_{u}^{″} (t)}{N_{u} (t)} - ρ (t) {(\frac{N_{u}^{'} (t)}{N_{u} (t)})}^{2} \\ \leq & \frac{ρ^{'} (t)}{ρ (t)} w (t) - \frac{1}{ρ (t)} w^{2} (t) \\ - c_{2}^{β / α} ρ (t) N_{u}^{β / α - 1} (t) \int_{t}^{\infty} {(\frac{1}{r (ϱ)} \int_{ϱ}^{\infty} q (s) {(\frac{τ^{- 1} (σ (s))}{s})}^{β} d s)}^{1 / α} d ϱ . \end{matrix}

Thus, we obtain

w^{'} (t) \leq - Φ (t) + \frac{ρ^{'} (t)}{ρ (t)} w (t) - \frac{1}{ρ (t)} w^{2} (t)

and so

w^{'} (t) \leq - Φ (t) + \frac{{(ρ^{'} (t))}^{2}}{4 ρ (t)} .

Then, we get

\int_{t_{1}}^{t} (Φ (s) - \frac{{(ρ^{'} (t))}^{2}}{4 ρ (t)}) d s \leq w (t_{1}),

which contradicts (17). This completes the proof. □

Example 1.

Consider the equation

{(u (t) + c_{0} u (δ t))}^{(4)} + \frac{q_{0}}{t^{4}} u (λ t) = 0,

(22)

where

t \geq 1, q_{0} > 0,

δ \in (c_{0}^{- 1 / 3}, 1)

and

λ \in (0, δ) .

We note that

r (t) = 1,

c (t) = c_{0},

τ (t) = δ t, σ (t) = λ t

and

q (t) = q_{0} / t^{4}

. Thus, it’s easy to see that (6) is satisfied. Moreover, we have

c_{1} (t) = \frac{1}{c_{0}} (1 - \frac{1}{δ^{3} c_{0}}), c_{2} (t) = \frac{1}{c_{0}} (1 - \frac{1}{δ c_{0}}), Ψ (t) = \frac{c_{1} q_{0}}{t}

and

Φ (t) = \frac{c_{2} λ q_{0}}{6 δ t} .

Thus, (16) and (17) become

\int_{t_{0}}^{\infty} (\frac{c_{1} (t) q_{0}}{s} - \frac{9 δ^{4}}{2 λ^{4}} \frac{1}{s}) d s = (c_{1} (t) q_{0} - \frac{9 δ^{4}}{2 λ^{4}}) (+ \infty)

and

\int_{t_{0}}^{\infty} (Φ (s) - \frac{{(ρ^{'} (s))}^{2}}{4 ρ (s)}) d s = (\frac{c_{2} λ}{6 δ} q_{0} - \frac{1}{4}) (+ \infty),

respectively. Hence, from Theorem 4, we conclude that (22) is oscillatory if

q_{0} \frac{1}{c_{0}} (1 - \frac{1}{δ^{3} c_{0}}) > \frac{9 δ^{4}}{2 λ^{4}}

(23)

and

q_{0} \frac{1}{c_{0}} (1 - \frac{1}{δ c_{0}}) > \frac{3 δ}{2 λ} .

(24)

In particular case that

c_{0} = 16,

δ = 1 / 2

and

λ = 1 / 3

, Condition (23) yields

q_{0} > 41.14

. Whereas, the criterion obtained from the results of [22] is

q_{0} > 4850.4

. Hence, our results improve the results in [22].

Author Contributions

The authors claim to have contributed equally and significantly in this paper. All authors read and approved the final manuscript.

Funding

The authors received no direct funding for this work.

Acknowledgments

The authors thank the reviewers for for their useful comments, which led to the improvement of the content of the paper.

Conflicts of Interest

The authors declare no conflict of interest.

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Moaaz, O.; El-Nabulsi, R.A.; Bazighifan, O. Oscillatory Behavior of Fourth-Order Differential Equations with Neutral Delay. Symmetry 2020, 12, 371. https://doi.org/10.3390/sym12030371

AMA Style

Moaaz O, El-Nabulsi RA, Bazighifan O. Oscillatory Behavior of Fourth-Order Differential Equations with Neutral Delay. Symmetry. 2020; 12(3):371. https://doi.org/10.3390/sym12030371

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Moaaz, Osama, Rami Ahmad El-Nabulsi, and Omar Bazighifan. 2020. "Oscillatory Behavior of Fourth-Order Differential Equations with Neutral Delay" Symmetry 12, no. 3: 371. https://doi.org/10.3390/sym12030371

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Oscillatory Behavior of Fourth-Order Differential Equations with Neutral Delay

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