Multiple Techniques for Studying Asymptotic Properties of a Class of Differential Equations with Variable Coefficients

Bazighifan, Omar; Postolache, Mihai

doi:10.3390/sym12071112

Open AccessArticle

Multiple Techniques for Studying Asymptotic Properties of a Class of Differential Equations with Variable Coefficients

by

Omar Bazighifan

^1,2,*,†

and

Mihai Postolache

^3,4,5,*,†

¹

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

²

Department of Mathematics, Faculty of Education, Seiyun University, Hadhramout 50512, Yemen

³

Center for General Education, China Medical University, Taichung 40402, Taiwan

⁴

Department of Mathematics and Informatics, University Politehnica of Bucharest, 060042 Bucharest, Romania

⁵

Gh. Mihoc-C. Iacob Institute of Mathematical Statistics and Applied Mathematics, Romanian Academy, 050711 Bucharest, Romania

^*

Authors to whom correspondence should be addressed.

^†

These authors contributed equally to this work.

Symmetry 2020, 12(7), 1112; https://doi.org/10.3390/sym12071112

Submission received: 16 April 2020 / Revised: 22 May 2020 / Accepted: 11 June 2020 / Published: 3 July 2020

(This article belongs to the Special Issue Advance in Nonlinear Analysis and Optimization)

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Abstract

:

This manuscript is concerned with the oscillatory properties of 4th-order differential equations with variable coefficients. The main aim of this paper is the combination of the following three techniques used: the comparison method, Riccati technique and integral averaging technique. Two examples are given for applying the criteria.

Keywords:

delay differential equations; oscillation; fourth-order

1. Introduction

Differential equations of fourth-order have applications in dynamical systems, optimization, and in the mathematical modeling of engineering problems [1]. The p-Laplace equations have some significant applications in elasticity theory and continuum mechanics, see, for example, [2,3]. Symmetry plays an important role in determining the right way to study these equations [4]. The main aim of this paper is the combination of the following three techniques used:

(a): The comparison method.
(b): Riccati technique.
(c): Integral averaging technique.

We consider the following fourth-order delay differential equations with p-Laplacian like operators

{(a (ζ) {|u^{‴} (ζ)|}^{p - 2} u^{‴} (ζ))}^{'} + q (ζ) g (u (η (ζ))) = 0,

(1)

where

ζ \geq ζ_{0}

. Throughout this work, we suppose that:

K1:: $p > 1$ is a real number.
K2:: $a \in C^{1} ([ζ_{0}, \infty), R),$ $a (ζ) > 0, a^{'} (ζ) \geq 0$ and under the condition

$\int_{ζ_{0}}^{\infty} \frac{1}{a^{1 / (p - 1)} (s)} d s = \infty,$

(2)
K3:: $q \in C ([ζ_{0}, \infty), R),$ $q (ζ) > 0,$
K4:: $η \in C ([ζ_{0}, \infty), R), η (ζ) \leq ζ,$ $lim_{ζ \to \infty} η (ζ) = \infty,$
K5:: $g \in C (R, R)$ such that $g (u) \geq m {|u|}^{p - 2} u > 0,$ for $u \neq 0$ and m is a constant.

Definition 1.

The function

u \in C^{3} [ζ_{u}, \infty), ζ_{u} \geq ζ_{0}

is called a solution of (1), if

a (ζ) {|u^{‴} (ζ)|}^{p - 2} u^{‴} (ζ) \in C^{1} [ζ_{u}, \infty),

and

u (ζ)

satisfies (1) on

[ζ_{u}, \infty)

. Moreover, the equation (1) is oscillatory if all its solutions oscillate.

In the last few decades, there have been a constant interest to investigate the asymptotic property for oscillations of differential equation, see [5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25]. Furthermore, there are some results that study the oscillatory behavior of 4th-order equations with p-Laplacian, we refer the reader to [26,27].

Now the following results are presented.

Grace and Lalli [28], Karpuz et al. [29] and Zafer [30] studied the even-order equation

u^{(γ)} (ζ) + q (ζ) u (η (ζ)) = 0,

they used the Riccati substitution to find several oscillation criteria and established the following results, respectively:

\int_{ζ_{0}}^{\infty} (δ (s) q (s) - \frac{(γ - 1)! {(δ^{'} (s))}^{2}}{2^{3 - 2 γ} η^{γ - 2} (s) η^{'} (s) δ (s)}) d s = \infty,

(3)

where

δ \in C^{1} ([ζ_{0}, \infty), (0, \infty)) .

\underset{ζ \to \infty}{lim inf} \int_{η (ζ)}^{ζ} q (s) η^{γ - 2} (s) d s > \frac{(γ - 1) 2^{(γ - 1) (γ - 2)}}{e}

(4)

and

\underset{ζ \to \infty}{lim inf} \int_{η (ζ)}^{ζ} q (s) η^{γ - 2} (s) d s > \frac{(γ - 1)!}{e} .

(5)

Zhang et al. [31,32] studied the even-order equation

{(a (ζ) {(u^{(γ - 1)} (ζ))}^{β})}^{'} + q (ζ) u^{β} (η (ζ)) = 0,

(6)

where

β

is a quotient of odd positive integers. They proved that it is oscillatory, if

\underset{ζ \to \infty}{lim inf} \int_{ζ}^{η (ζ)} \frac{q (s)}{a (η (s))} {(η^{γ - 2} (s))}^{β} d s > \frac{{((γ - 1)!)}^{β}}{e},

(7)

where

γ \geq 2

is even and they used the compare with first order equations. If there exists a function

δ \in C^{1} ([ζ_{0}, \infty), (0, \infty))

for all constants

M > 0

such that

\underset{ζ \to \infty}{lim inf} \int_{ζ_{0}}^{\infty} δ (s) (q (s) - \frac{a (s) {(θ M η^{γ - 2} (s) η^{'} (s))}^{1 - p}}{p^{p}} {(\frac{δ^{'} (s)}{δ (s)} - \frac{a (s)}{r (s)})}^{p}) d s = \infty,,

(8)

for some constant

θ \in (0, 1) .

Our aim in this work is to complement results in [28,29,30,31,32]. Two examples are given for applying the criteria.

2. Some Auxiliary Lemmas

Lemma 1.

[13] Fixing

V > 0

and

U \geq 0

, we have that

U x - V x^{(β + 1) / β} \leq \frac{β^{β}}{{(β + 1)}^{β + 1}} \frac{U^{β + 1}}{V^{β}} .

Lemma 2.

[14] For

i = 0, 1, \dots, γ,

let

u^{(i)} (ζ) > 0,

and

u^{(γ + 1)} (ζ) < 0,

then

\frac{u (ζ)}{ζ^{γ} / γ!} \geq \frac{u^{'} (ζ)}{ζ^{γ - 1} / (γ - 1)!} .

Lemma 3.

[16] Suppose that

u

is an eventually positive solution of (1). Then, we distinguish the following situations:

\begin{matrix} (S_{1}) & u (ζ) > 0, u^{'} (ζ) > 0, u^{″} (ζ) > 0, u^{‴} (ζ) > 0, u^{(4)} (ζ) < 0, \\ (S_{2}) & u (ζ) > 0, u^{'} (ζ) > 0, u^{″} (ζ) < 0, u^{‴} (ζ) > 0, u^{(4)} (ζ) < 0, \end{matrix}

for

ζ \geq ζ_{1},

where

ζ_{1} \geq ζ_{0}

is sufficiently large.

3. Main Results

Let the differential equation

{[a (ζ) {(u^{'} (ζ))}^{β}]}^{'} + q (ζ) u^{β} (g (ζ)) = 0 ζ \geq ζ_{0,}

(9)

where a,

q \in C ([ζ_{0}, \infty), R^{+})

, is nonoscillatory if and only if

ζ \geq ζ_{0}

, and a function

ς \in C^{1} ([ζ, \infty), R),

satisfying the inequality

ς^{'} (ζ) + γ a^{- 1 / β} (ζ) {(ς (ζ))}^{(1 + β) / β} + q (ζ) \leq 0 on [ζ, \infty) .

Definition 2.

Let

D = {(ζ, s) \in R^{2} : ζ \geq s \geq ζ_{0}} a n d D_{0} = {(ζ, s) \in R^{2} : ζ > s \geq ζ_{0}} .

A kernel function

H_{i} \in C (D, R)

is said to belong to the function class ℑ, written by

H \in ℑ

, if, for

i = 1, 2

,

(i): $H_{i} (ζ, s) = 0$ for $ζ \geq ζ_{0}, H_{i} (ζ, s) > 0, (ζ, s) \in D_{0};$
(ii): $H_{i} (ζ, s)$ has a continuous and nonpositive partial derivative $\partial H_{i} / \partial s$ on $D_{0}$ and there exist functions $δ, ϑ \in C^{1} ([ζ_{0}, \infty), (0, \infty))$ and $h_{i} \in C (D_{0}, R)$ such that

$\frac{\partial}{\partial s} H_{1} (ζ, s) + \frac{δ^{'} (s)}{δ (s)} H_{1} (ζ, s) = h_{1} (ζ, s) H_{1}^{β / (β + 1)} (ζ, s)$

(10)

and

$\frac{\partial}{\partial s} H_{2} (ζ, s) + \frac{ϑ^{'} (s)}{ϑ (s)} H_{2} (ζ, s) = h_{2} (ζ, s) \sqrt{H_{2} (ζ, s)} .$

(11)

Theorem 1.

Let (2) holds. If the equations

{(\frac{2 a^{\frac{1}{p - 1}} (ζ)}{{(θ ζ^{2})}^{p - 1}} {(u^{'} (ζ))}^{p - 1})}^{'} + k q (ζ) {(\frac{η^{3} (ζ)}{ζ^{3}})}^{p - 1} u^{p - 1} (ζ) = 0

(12)

and

u^{″} (ζ) + u (ζ) \int_{ζ}^{\infty} {(\frac{1}{a (ς)} \int_{ς}^{\infty} q (s) {(\frac{η (ζ)}{ζ})}^{p - 1} d s)}^{1 / p - 1} d ς = 0

(13)

are oscillatory, then every solution of (1) is oscillatory.

Proof.

Assume, for the sake of contradiction, that u is a positive solution of (1). Then, we let

u (ζ) > 0

and

u (η (ζ)) > 0

. By Lemma 3, we have

(S_{1})

and

(S_{2})

.

Let case

(S_{1})

holds. Using [25], [Lemma 2.2.3], we find

u^{'} (ζ) \geq \frac{θ}{2} ζ^{2} u^{‴} (ζ),

(14)

for every

θ \in (0, 1)

.

From Lemma 2, we get

\frac{u^{'} (ζ)}{u (ζ)} \leq \frac{3}{ζ} .

Integrating from

η (ζ)

to

ζ

, we find

\frac{u (η (ζ))}{u (ζ)} \geq \frac{η^{3} (ζ)}{ζ^{3}} .

(15)

Defining

φ (ζ) : = δ (ζ) (\frac{a (ζ) {(u^{‴} (ζ))}^{p - 1}}{u^{p - 1} (ζ)}), φ (ζ) > 0,

(16)

where

δ \in C^{1} ([ζ_{0}, \infty), (0, \infty))

and

\begin{matrix} φ^{'} (ζ) = δ^{'} (ζ) \frac{a (ζ) {(u^{‴} (ζ))}^{p - 1}}{u^{p - 1} (ζ)} + δ (ζ) \frac{{(a {(u^{‴})}^{p - 1})}^{'} (ζ)}{u^{p - 1} (ζ)} \\ - (p - 1) δ (ζ) \frac{u^{p - 2} (ζ) u^{'} (ζ) a (ζ) {(u^{‴} (ζ))}^{p - 1}}{u^{2 (p - 1)} (ζ)} . \end{matrix}

Combining (14) and (16), we obtain

\begin{matrix} φ^{'} (ζ) \leq \frac{δ_{+}^{'} (ζ)}{δ (ζ)} φ (ζ) + δ (ζ) \frac{{(a (ζ) {(u^{‴} (ζ))}^{p - 1})}^{'}}{u^{p - 1} (ζ)} \\ - (p - 1) δ (ζ) \frac{θ}{2} ζ^{2} \frac{a (ζ) {(u^{‴} (ζ))}^{p}}{u^{p} (ζ)} \\ \leq \frac{δ^{'} (ζ)}{δ (ζ)} φ (ζ) + δ (ζ) \frac{{(a (ζ) {(u^{‴} (ζ))}^{β})}^{'}}{u^{β} (ζ)} \\ - \frac{(p - 1) θ ζ^{2}}{2 {(δ (ζ) a (ζ))}^{\frac{1}{p - 1}}} φ^{\frac{p}{p - 1}} (ζ) . \end{matrix}

(17)

From (1) and (17), we find

φ^{'} (ζ) \leq \frac{δ^{'} (ζ)}{δ (ζ)} φ (ζ) - m δ (ζ) \frac{q (ζ) u^{p - 1} (η (ζ))}{u^{p - 1} (ζ)} - \frac{(p - 1) θ ζ^{2}}{2 {(δ (ζ) a (ζ))}^{\frac{1}{p - 1}}} φ^{\frac{p}{p - 1}} (ζ) .

From (15), we have

φ^{'} (ζ) \leq \frac{δ^{'} (ζ)}{δ (ζ)} φ (ζ) - m δ (ζ) q (ζ) {(\frac{η^{3} (ζ)}{ζ^{3}})}^{p - 1} - \frac{(p - 1) θ ζ^{2}}{2 {(δ (ζ) a (ζ))}^{\frac{1}{p - 1}}} φ^{\frac{p}{p - 1}} (ζ) .

(18)

Let

δ (ζ) = m = 1

in (18), we have

φ^{'} (ζ) + \frac{(p - 1) θ ζ^{2}}{2 a^{\frac{1}{p - 1}} (ζ)} φ^{\frac{p}{p - 1}} (ζ) + q (ζ) {(\frac{η^{3} (ζ)}{ζ^{3}})}^{p - 1} \leq 0 .

Hence, the equation (12) is nonoscillatory

,

which is a contradiction.

Let case

(S_{2})

holds. By Lemma 2, we find

\frac{u^{'} (ζ)}{u (ζ)} \leq \frac{1}{ζ} .

Integrating again from

η (ζ)

to

ζ

, we find

\frac{u (η (ζ))}{u (ζ)} \geq \frac{η (ζ)}{ζ} .

(19)

Defining

ψ (ζ) : = ϑ (ζ) \frac{u^{'} (ζ)}{u (ζ)} > 0,

where

ϑ \in C^{1} ([ζ_{0}, \infty), (0, \infty))

and

ψ^{'} (ζ) = \frac{ϑ^{'} (ζ)}{ϑ (ζ)} ψ (ζ) + ϑ (ζ) \frac{u^{″} (ζ)}{u (ζ)} - \frac{1}{ϑ (ζ)} ψ {(ζ)}^{2} .

(20)

Integrating (1) from

ζ

to x and using

u^{'} (ζ) > 0

, we have

a (x) {(u^{‴} (x))}^{p - 1} - a (ζ) {(u^{‴} (ζ))}^{p - 1} = - \int_{ζ}^{x} q (s) g (u (η (s))) d s .

From (19), we get

a (x) {(u^{‴} (x))}^{p - 1} - a (ζ) {(u^{‴} (ζ))}^{p - 1} \leq - k y^{p - 1} (ζ) \int_{ζ}^{x} q (s) {(\frac{η (s)}{s})}^{p - 1} d s .

Letting

x \to \infty

, we have

a (ζ) {(u^{‴} (ζ))}^{p - 1} \geq k y^{p - 1} (ζ) \int_{ζ}^{\infty} q (s) {(\frac{η (s)}{s})}^{p - 1} d s

and so

u^{'''} (ζ) \geq u (ζ) {(\frac{m}{a (ζ)} \int_{ζ}^{\infty} q (s) {(\frac{η (s)}{s})}^{p - 1} d s)}^{1 / (p - 1)} .

Integrating again from

ζ

to ∞, we get

u^{''} (ζ) + u (ζ) \int_{ζ}^{\infty} {(\frac{m}{a (ς)} \int_{ς}^{\infty} q (s) {(\frac{η (s)}{s})}^{p - 1} d s)}^{1 / (p - 1)} d ς \leq 0 .

(21)

Combining (20) and (21), we find

ψ^{'} (ζ) \leq \frac{ϑ^{'} (ζ)}{ϑ (ζ)} ψ (ζ) - ϑ (ζ) \int_{ζ}^{\infty} {(\frac{m}{a (ς)} \int_{ς}^{\infty} q (s) {(\frac{η (s)}{s})}^{p - 1} d s)}^{1 / (p - 1)} d ς - \frac{1}{ϑ (ζ)} ψ {(ζ)}^{2} .

(22)

If

ϑ (ζ) = m = 1

in (22), we get

ψ^{'} (ζ) + ψ^{2} (ζ) + \int_{ζ}^{\infty} {(\frac{1}{a (ς)} \int_{ς}^{\infty} q (s) {(\frac{η (s)}{s})}^{p - 1} d s)}^{1 / (p - 1)} d ς \leq 0 .

Thus, the Equation (13) is nonoscillatory, which is a contradiction. The proof of the theorem is complete. ☐

Next, we obtain the following Hille and Nehari type oscillation criteria for (1) with

p = 2 .

Theorem 2.

Let

p = 2, m = 1 .

Assume that

\int_{ζ_{0}}^{\infty} \frac{θ ζ^{2}}{2 a (ζ)} d ζ = \infty

and

\underset{ζ \to \infty}{lim inf} (\int_{ζ_{0}}^{ζ} \frac{θ s^{2}}{2 a (s)} d s) \int_{ζ}^{\infty} q (s) (\frac{η^{3} (s)}{s^{3}}) d s > \frac{1}{4},

(23)

for some constant

θ \in (0, 1),

\underset{ζ \to \infty}{lim inf} ζ \int_{ζ_{0}}^{ζ} \int_{v}^{\infty} (\frac{1}{a (ς)} \int_{ς}^{\infty} q (s) (\frac{η (s)}{s}) d s) d ς d v > \frac{1}{4},

(24)

then all solutions of (1) is oscillatory.

In this theorem, we use the integral averaging technique:

Theorem 3.

Let (2) holds. If there exist positive functions

δ, ϑ \in C^{1} ([ζ_{0}, \infty), R)

such that

\underset{ζ \to \infty}{lim sup} \frac{1}{H_{1} (ζ, ζ_{1})} \int_{ζ_{1}}^{ζ} (H_{1} (ζ, s) m δ (s) q (s) {(\frac{η^{3} (s)}{s^{3}})}^{p - 1} - π (s)) d s = \infty

(25)

and

\underset{ζ \to \infty}{lim sup} \frac{1}{H_{2} (ζ, ζ_{1})} \int_{ζ_{1}}^{ζ} (H_{2} (ζ, s) ϑ (s) ϖ (s) - \frac{ϑ (s) h_{2}^{2} (ζ, s)}{4}) d s = \infty,

(26)

where

π (s) = \frac{h_{1}^{p} (ζ, s) H_{1}^{p - 1} (ζ, s)}{p^{p}} \frac{2^{p - 1} δ (s) a (s)}{{(θ s^{2})}^{p - 1}},

for all

θ \in (0, 1),

and

ϖ (s) = {(\frac{1}{a (ς)} \int_{ς}^{\infty} q (s) {(\frac{η (s)}{s})}^{p - 1} d s)}^{1 / (p - 1)} d ς,

then (1) is oscillatory.

Proof.

Proceeding as in the proof of Theorem 1. Assume that

(S_{1})

holds. From Theorem 1, we get that (18) holds. Multiplying (18) by

H_{1} (ζ, s)

and integrating the resulting inequality from

ζ_{1}

to

ζ

, we find that

\begin{matrix} \int_{ζ_{1}}^{ζ} H_{1} (ζ, s) m δ (s) q (s) {(\frac{η^{3} (s)}{s^{3}})}^{p - 1} d s & \leq & φ (ζ_{1}) H_{1} (ζ, ζ_{1}) + \int_{ζ_{1}}^{ζ} (\frac{\partial}{\partial s} H_{1} (ζ, s) + \frac{δ^{'} (s)}{δ (s)} H_{1} (ζ, s)) φ (s) d s \\ - \int_{ζ_{1}}^{ζ} \frac{(p - 1) θ s^{2}}{2 {(δ (s) a (s))}^{\frac{1}{p - 1}}} H_{1} (ζ, s) φ^{\frac{p}{p - 1}} (s) d s . \end{matrix}

From (10), we get

\begin{matrix} \int_{ζ_{1}}^{ζ} H_{1} (ζ, s) m δ (s) q (s) {(\frac{η^{3} (s)}{s^{3}})}^{p - 1} d s & \leq & φ (ζ_{1}) H_{1} (ζ, ζ_{1}) + \int_{ζ_{1}}^{ζ} h_{1} (ζ, s) H_{1}^{(p - 1) / p} (ζ, s) φ (s) d s \\ - \int_{ζ_{1}}^{ζ} \frac{(p - 1) θ s^{2}}{2 {(δ (s) a (s))}^{\frac{1}{p - 1}}} H_{1} (ζ, s) φ^{\frac{p}{p - 1}} (s) d s . \end{matrix}

(27)

Using Lemma 1 with

V = (p - 1) θ s^{2} / (2 {(δ (s) a (s))}^{\frac{1}{p - 1}}) H_{1} (ζ, s), U = h_{1} (ζ, s) H_{1}^{(p - 1) / p} (ζ, s)

and

u = φ (s)

, we get

\begin{matrix} h_{1} (ζ, s) H_{1}^{(p - 1) / p} (ζ, s) φ (s) - \frac{(p - 1) θ s^{2}}{2 {(δ (s) a (s))}^{\frac{1}{p - 1}}} H_{1} (ζ, s) φ^{\frac{p}{p - 1}} (s) \\ \leq \frac{h_{1}^{p} (ζ, s) H_{1}^{p - 1} (ζ, s)}{p^{p}} \frac{2^{p - 1} δ (s) a (s)}{{(θ s^{2})}^{p - 1}}, \end{matrix}

which, with (27) gives

\frac{1}{H_{1} (ζ, ζ_{1})} \int_{ζ_{1}}^{ζ} (H_{1} (ζ, s) m δ (s) q (s) {(\frac{η^{3} (s)}{s^{3}})}^{p - 1} - π (s)) d s \leq φ (ζ_{1}) .

This contradicts (25).

Assume that

(S_{2})

holds. From Theorem 1, (22) holds. Multiplying (22) by

H_{2} (ζ, s)

and integrating the resulting inequality from

ζ_{1}

to

ζ

, we get

\begin{matrix} \int_{ζ_{1}}^{ζ} H_{2} (ζ, s) ϑ (s) ϖ (s) d s & \leq & ψ (ζ_{1}) H_{2} (ζ, ζ_{1}) \\ + \int_{ζ_{1}}^{ζ} (\frac{\partial}{\partial s} H_{2} (ζ, s) + \frac{ϑ^{'} (s)}{ϑ (s)} H_{2} (ζ, s)) ψ (s) d s \\ - \int_{ζ_{1}}^{ζ} \frac{1}{ϑ (s)} H_{2} (ζ, s) ψ^{2} (s) d s . \end{matrix}

Thus, from (11), we get

\begin{matrix} \int_{ζ_{1}}^{ζ} H_{2} (ζ, s) ϑ (s) ϖ (s) d s & \leq & ψ (ζ_{1}) H_{2} (ζ, ζ_{1}) + \int_{ζ_{1}}^{ζ} h_{2} (ζ, s) \sqrt{H_{2} (ζ, s)} ψ (s) d s \\ - \int_{ζ_{1}}^{ζ} \frac{1}{ϑ (s)} H_{2} (ζ, s) ψ^{2} (s) d s \\ \leq & ψ (ζ_{1}) H_{2} (ζ, ζ_{1}) + \int_{ζ_{1}}^{ζ} \frac{ϑ (s) h_{2}^{2} (ζ, s)}{4} d s \end{matrix}

and so

\frac{1}{H_{2} (ζ, ζ_{1})} \int_{ζ_{1}}^{ζ} (H_{2} (ζ, s) ϑ (s) ϖ (s) - \frac{ϑ (s) h_{2}^{2} (ζ, s)}{4}) d s \leq ψ (ζ_{1}),

which contradicts (26). The proof of the theorem is complete.

Example 1.

Consider the equation

u^{(4)} (ζ) + \frac{q_{0}}{ζ^{4}} u (\frac{9 ζ}{10}) = 0, ζ \geq 1, q_{0} > 0 .

(28)

Let

p = 2, a (ζ) = 1, q (ζ) = q_{0} / ζ^{4}

and

η (ζ) = 9 ζ / 10

. If we set

m = 1, H_{1} (ζ, s) = {(ζ - s)}^{2}

and

δ (s) = s^{3},

then

h_{1} (ζ, s) = (ζ - s) (5 - 3 ζ s^{- 1}),

and conditions (23) becomes

\begin{matrix} \underset{ζ \to \infty}{lim sup} \frac{1}{H_{1} (ζ, ζ_{1})} \int_{ζ_{1}}^{ζ} (H_{1} (ζ, s) m δ (s) q (s) {(\frac{η^{3} (s)}{s^{3}})}^{p - 1} - π (s)) d s \\ = \underset{ζ \to \infty}{lim sup} \frac{1}{{(ζ - 1)}^{2}} \int_{ζ_{1}}^{ζ} (\frac{729 q_{0} ζ^{2} s^{- 1}}{1000} + \frac{729 q_{0} s}{1000} - \frac{729 q_{0} ζ}{500} - \frac{s (25 + 9 ζ^{2} s^{- 2} - 30 ζ s^{- 1})}{2 θ}) d s \\ = \infty, \end{matrix}

if

q_{0} > 500 / (81 θ)

for some

θ \in (0, 1)

, letting

θ = 81 / 82,

then

q_{0} > 6.25 .

Also, set

H_{2} (ζ, s) = {(ζ - s)}^{2}

and

ϑ (s) = s,

then

h_{2} (ζ, s) = (ζ - s) (3 - ζ s^{- 1}), ϖ (s) = 3 q_{0} / (20 ζ^{2})

and conditions (24) becomes

\begin{matrix} \underset{ζ \to \infty}{lim sup} \frac{1}{H_{2} (ζ, ζ_{1})} \int_{ζ_{1}}^{ζ} (H_{2} (ζ, s) ϑ (s) ϖ (s) - \frac{ϑ (s) h_{2}^{2} (ζ, s)}{4}) d s \\ = \underset{ζ \to \infty}{lim sup} \frac{1}{{(ζ - 1)}^{2}} \int_{ζ_{1}}^{ζ} (\frac{3 q_{0} ζ^{2} s^{- 1}}{20} + \frac{3 q_{0} s}{20} - \frac{3 q_{0} ζ}{10} - \frac{s (9 - 6 ζ s^{- 1} + ζ^{2} s^{- 2})}{4}) d s \\ = \infty, \end{matrix}

if

q_{0} > 5 / 3

, From Theorem 3, all solutions of (28) are oscillatory, if

q_{0} > 6.25

.

Remark 1.

By comparing our results with previous results

1. By applying condition (3) in [28], we get

q_{0} > 1728,

2. By applying condition (4) in [29], we get

q_{0} > 919.6,

3. By applying condition (5) in [30], we get

q_{0} > 28.73,

4. By applying condition (7) in [31], we get

q_{0} > 28.73,

5. The condition (8) in [32] cannot be applied to Equation (28) due to the arbitrariness in the choice of θ. Therefore, our result complement results [28,29,30,31,32].

Example 2.

Let the equation

u^{(4)} (ζ) + \frac{q_{0}}{ζ^{4}} u (\frac{1}{2} ζ) = 0, ζ \geq 1, q_{0} > 0 .

(29)

Let

a (ζ) = 1, q (ζ) = q_{0} / ζ^{4}

and

η (ζ) = ζ / 2

. If we set

m = 1,

then condition (23) becomes

\begin{matrix} \underset{ζ \to \infty}{lim inf} (\int_{ζ_{0}}^{ζ} \frac{θ s^{2}}{2 a (s)} d s) \int_{ζ}^{\infty} q (s) (\frac{η^{3} (s)}{s^{3}}) d s & = & \underset{ζ \to \infty}{lim inf} (\frac{ζ^{3}}{3}) \int_{ζ}^{\infty} \frac{q_{0}}{8 s^{4}} d s \\ = & \frac{q_{0}}{72} > \frac{1}{4} \end{matrix}

and condition (24) becomes

\begin{matrix} \underset{ζ \to \infty}{lim inf} ζ \int_{ζ_{0}}^{ζ} \int_{v}^{\infty} (\frac{1}{a (ς)} \int_{ς}^{\infty} q (s) (\frac{η (s)}{s}) d s) d ς d v & = & \underset{ζ \to \infty}{lim inf} ζ (\frac{q_{0}}{12 ζ}) \\ = & \frac{q_{0}}{12} > \frac{1}{4} . \end{matrix}

Hence, by Theorem 2, all solution equation (29) is oscillatory if

q_{0} > 18

.

Remark 2.

We point out that continuing this line of work, we can have oscillatory results for a fourth order equation of the type:

{(a (ζ) {|u^{'''} (ζ)|}^{p - 2} u^{‴} (ζ))}^{'} + \sum_{i = 1}^{m} q_{i} (ζ) {|u (η_{i} (ζ))|}^{p - 2} u (η_{i} (ζ)) = 0, where ζ \geq ζ_{0}, m \geq 1,

under the condition

\int_{ζ_{0}}^{\infty} \frac{1}{a^{1 / (p - 1)} (s)} d s < \infty .

4. Conclusions

In this article, we studied some oscillation conditions for 4th-order differential equations by the comparison method, Riccati technique and integral averaging technique.

Further, in the future work we study Equation (1) under the condition

\int_{ζ_{0}}^{\infty} \frac{1}{a^{1 / (p - 1)} (s)} d s < \infty .

Author Contributions

O.B.: Writing original draft, writing review and editing. M.P.: Formal analysis, writing review and editing, funding and supervision. All authors have read and agreed to the published version of the 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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Bazighifan, O.; Postolache, M. Multiple Techniques for Studying Asymptotic Properties of a Class of Differential Equations with Variable Coefficients. Symmetry 2020, 12, 1112. https://doi.org/10.3390/sym12071112

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Bazighifan O, Postolache M. Multiple Techniques for Studying Asymptotic Properties of a Class of Differential Equations with Variable Coefficients. Symmetry. 2020; 12(7):1112. https://doi.org/10.3390/sym12071112

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Bazighifan, Omar, and Mihai Postolache. 2020. "Multiple Techniques for Studying Asymptotic Properties of a Class of Differential Equations with Variable Coefficients" Symmetry 12, no. 7: 1112. https://doi.org/10.3390/sym12071112

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Multiple Techniques for Studying Asymptotic Properties of a Class of Differential Equations with Variable Coefficients

Abstract

1. Introduction

2. Some Auxiliary Lemmas

3. Main Results

4. Conclusions

Author Contributions

Funding

Acknowledgments

Conflicts of Interest

References

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