Extended Approach to the Asymptotic Behavior and Symmetric Solutions of Advanced Differential Equations

Bazighifan, Omar; Ali, Ali Hasan; Mofarreh, Fatemah; Raffoul, Youssef N.

doi:10.3390/sym14040686

Open AccessArticle

Extended Approach to the Asymptotic Behavior and Symmetric Solutions of Advanced Differential Equations

¹

Section of Mathematics, International Telematic University Uninettuno, Corso Vittorio Emanuele II, 39, 00186 Roma, Italy

²

Doctoral School of Mathematical and Computational Sciences, University of Debrecen, H-4002 Debrecen, Hungary

³

Mathematical Science Department, Faculty of Science, Princess Nourah Bint Abdulrahman University, Riyadh 11546, Saudi Arabia

⁴

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

^*

Author to whom correspondence should be addressed.

^†

These authors contributed equally to this work.

Symmetry 2022, 14(4), 686; https://doi.org/10.3390/sym14040686

Submission received: 28 February 2022 / Revised: 19 March 2022 / Accepted: 24 March 2022 / Published: 26 March 2022

(This article belongs to the Special Issue Differential/Difference Equations and Its Application)

Download Versions Notes

Abstract

:

We studied the asymptotic behavior of fourth-order advanced differential equations of the form

{(a (υ) {(w^{'''} (υ))}^{β})}^{'} + q (υ) g (w (δ (υ))) = 0

. New results are presented for the oscillatory behavior of these equations in the form of Philos-type and Hille–Nehari oscillation criteria. Some illustrative examples are presented.

Keywords:

Philos-type oscillation criteria; Hille–Nehari-type oscillation criteria; asymptotic behavior; fourth-order equations; advanced differential equations

MSC:

34K11

1. Introduction

As is well known, differential equations have many real-world applications [1]. Advanced differential equations, in particular, find applications in dynamical systems, mathematics of networks, optimization, and in the mathematical modeling of engineering processes, such as those found in electrical power systems, materials, and energy [2]. In the last decade, one important area of active research is the study of the qualitative oscillation behavior of differential equations [3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18]. In this paper, we investigate the oscillation of fourth-order nonlinear advanced differential equations of the following form:

{(a (υ) {(w^{'''} (υ))}^{β})}^{'} + q (υ) g (w (δ (υ))) = 0,

(1)

where

υ \geq υ_{0}

. Our main aim is to complement and improve the results in [19,20,21]. To motivate that, we briefly review and put into context those and related results.

In [17,18], Zhang et al. obtain, under mild assumptions and with the help of the comparison method with first-order equations, an oscillation criterion ensuring that every solution w of equation

{({(w^{(κ - 1)} (υ))}^{β})}^{'} + q (υ) w^{α} (δ (υ)) = 0

(2)

with

δ (υ) \leq υ

,

α \leq β

,

κ

even, and

α, β

ratios of odd positive integers, is either oscillatory or satisfies

lim_{υ \to \infty} w (υ) = 0

. For the special case when

β = α

, Zhang et al. [22] obtain—under similar assumptions of those in [17,18], but now using the comparison method with second-order equations—some results on the asymptotic behavior of (2) in the case of

κ = 4

. Agarwal and Grace [19] and Agarwal et al. [20] study canonical even-order nonlinear advanced differential equations, as follows:

{({(w^{(κ - 1)} (υ))}^{β})}^{'} + q (υ) w^{β} (δ (υ)) = 0

(3)

by means of the Riccati transformation technique, establishing some oscillation criteria for (3) when

δ (υ) \geq υ

,

κ

is even, and

β

is a ratio of odd positive integers. As a special case, when

β = 1

, Equation (3) becomes

w^{(κ)} (υ) + q (υ) w (δ (υ)) = 0 .

(4)

Grace and Lalli [21] study the oscillation of (4), in the case when

κ

is even, under the following condition:

\int_{υ_{0}}^{\infty} \frac{1}{a^{1 / β} (s)} d s = \infty .

(5)

To prove their results, they apply previous mentioned results to the following equation:

w^{(κ)} (υ) + \frac{q_{0}}{υ^{κ}} w (λ υ) = 0, υ \geq 1 .

(6)

If we set

κ = 4

and

λ = 2

, then, by applying the conditions in [19,20,21] to Equation (6), we find the results in [20], which improve those of [21]. Moreover, the results in [19] improve the ones of [20,21]. Thus, our motivation here is to complement and improve the results of [19,20,21]. From them, we obtain new criteria for the oscillation of Equation (1).

The paper is organized as follows. We begin with Section 2 of preliminaries, fixing our assumptions and notations and recalling necessary definitions and results from the literature. Our results are then given in Section 3: we prove conditions assuring that every solution w of (1) is either oscillatory or satisfies

lim_{υ \to \infty} w (υ) = 0

(see Theorems 1 and 2 and Corollary 1). In Section 4, we give two simple examples for which previous results of the literature do not apply, while our Hille–Nehari-type oscillation criterion holds. We end with Section 5—conclusions and future works—posing an interesting and challenging open question.

2. Hypotheses and Preliminaries

Throughout the work, we assume the following assumptions to (1):

A₁:: $β$ is a quotient of odd positive integers;
A₂:: $a \in C^{1} ([υ_{0}, \infty), R)$ , $a (υ) > 0$ , and $a^{'} (υ) \geq 0$ with

$\int_{υ_{0}}^{\infty} \frac{1}{a^{1 / β} (s)} d s < \infty;$

(7)
A₃:: $q \in C ([υ_{0}, \infty), R)$ with $q (υ) \geq 0$ ;
A₄:: $δ \in C ([υ_{0}, \infty), R)$ with $δ (υ) \geq υ$ and $lim_{υ \to \infty} δ (υ) = \infty$ ;
A₅:: $g \in C (R, R)$ such that $g (x) / x^{β} \geq k > 0$ for $x \neq 0$ .

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

w \in C^{3} [υ_{w}, \infty)

,

υ_{w} \geq υ_{0}

, which has the property

a (υ) {(w^{'''} (υ))}^{β} \in C^{1} [υ_{w}, \infty)

and satisfies (1) on

[υ_{w}, \infty)

. We consider only those solutions w of (1) that satisfy

sup {|w (υ)| : υ \geq υ_{w}} > 0

. To prove our results, we make use of the following methods: (i) an integral averaging technique; (ii) Riccati transformation techniques; (iii) a comparison method with second-order differential equations.

Definition 1

(See [23]). We say that the differential equation

{[a (υ) {(w^{'} (υ))}^{β}]}^{'} + q (υ) w^{β} (g (υ)) = 0 υ \geq υ_{0,}

(8)

where

β > 0

is a ratio of odd positive integers and a,

q \in C ([υ_{0}, \infty), R^{+})

, is nonoscillatory, if there exists a number

υ \geq υ_{0}

and a function

ς \in C^{1} ([υ_{0}, \infty), R)

satisfying the inequality

ς^{'} (υ) + γ a^{- 1 / β} (υ) {(ς (υ))}^{(1 + β) / β} + q (υ) \leq 0

on

[υ_{0}, \infty)

.

Definition 2

(See [24]). Let

D = {(υ, s) \in R^{2} : υ \geq s \geq υ_{0}} and D_{0} = {(υ, s) \in R^{2} : υ > s \geq υ_{0}}

. A kernel function

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

(i = 1, 2, \dots, n)

is said to belong to the set ℑ, written by

H \in ℑ

, if, for

i = 1, 2

, one has:

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

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

(9)

and

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

(10)

Notation 1.

For convenience, we denote

\begin{matrix} ζ (s) & : = & \int_{υ_{0}}^{\infty} \frac{1}{a^{1 / β} (s)} d s, \\ π (s, υ) & : = & \frac{h_{1}^{β + 1} (υ, s) H_{1}^{β} (υ, s)}{{(β + 1)}^{β + 1}} \frac{2^{β} η (s) a (s)}{{(θ s^{2})}^{β}}, \\ \tilde{π} (s, υ) & : = & \frac{β^{β + 1} H_{3} (υ, s)}{{(β + 1)}^{β + 1}} \frac{1}{a^{1 / β} (s) ζ (s)} \end{matrix}

where

θ \in (0, 1)

, and

ϖ (υ) : = \int_{υ}^{\infty} {(\frac{k}{a (ς)} \int_{ς}^{\infty} q (s) d s)}^{1 / β} d ς .

We shall employ the following four lemmas:

Lemma 1

(See [18]). Suppose that

w \in C^{κ} ([υ_{0}, \infty), (0, \infty)),

w^{(κ)}

is of a fixed sign on

[υ_{0}, \infty)

,

w^{(κ)}

is not identically zero, and there exists a

υ_{1} \geq υ_{0}

, such that

w^{(κ - 1)} (υ) w^{(κ)} (υ) \leq 0

for all

υ \geq υ_{1}

. If we have

{lim}_{υ \to \infty} w (υ) \neq 0

, then there exists

υ_{θ} \geq υ_{1}

, such that

w (υ) \geq \frac{θ}{(κ - 1)!} υ^{κ - 1} |w^{(κ - 1)} (υ)|

for every

θ \in (0, 1)

and

υ \geq υ_{θ}

.

Lemma 2

(See [5]). If

w^{(i)} (υ) > 0

,

i = 0, 1, \dots, κ

, and

w^{(κ + 1)} (υ) < 0

, then

\frac{w (υ)}{υ^{κ} / κ!} \geq \frac{w^{'} (υ)}{υ^{κ - 1} / (κ - 1)!} .

Lemma 3

(See [4]). Let β be a ratio of two odd numbers and

V > 0

and U be two constants. Then,

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

Lemma 4

(See [25]). If w is a positive solution of (1), then there exist three possible situations for

υ \geq υ_{1}

, where

υ_{1} \geq υ_{0}

is sufficiently large:

$(S_{1})$: $w (υ) > 0$ , $w^{'} (υ) > 0$ , $w^{''} (υ) > 0$ , $w^{'''} (υ) > 0$ , $w^{(4)} (υ) < 0$ ,
$(S_{2})$: $w (υ) > 0$ , $w^{'} (υ) > 0$ , $w^{''} (υ) < 0$ , $w^{'''} (υ) > 0$ , $w^{(4)} (υ) < 0$ ,
$(S_{3})$: $w (υ) > 0, w^{''} (υ) > 0, w^{'''} (υ) < 0$ .

We are now in a position to formulate and prove our original results.

3. Main Results

In our first theorem, we employ an integral averaging technique to establish a Philos-type oscillation criterion.

Theorem 1

(Philos-type oscillation criterion for (1)). Under assumptions

A_{1}

–

A_{5}

, if there exist positive functions

η, ϑ \in C^{1} ([υ_{0}, \infty), R)

, such that

\underset{υ \to \infty}{lim sup} \frac{1}{H_{1} (υ, υ_{1})} \int_{υ_{1}}^{υ} (H_{1} (υ, s) k η (s) q (s) - π (s, υ)) d s = \infty

(11)

for all

θ \in (0, 1)

, if

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

(12)

and, for every

θ_{1} \in (0, 1)

,

\underset{υ \to \infty}{lim sup} \frac{1}{H_{3} (υ, υ_{1})} \int_{υ_{1}}^{υ} (H_{3} (υ, s) k q (s) {(\frac{θ_{1} δ^{2} (s)}{2})}^{β} ζ^{β} (δ (s)) - \tilde{π} (s, υ)) d s = \infty,

then every solution of (1) is either oscillatory or satisfies

lim_{υ \to \infty} w (υ) = 0

.

Proof.

Assume the contrary, that w is a positive solution of (1). Then, we can suppose that

w (υ)

and

w (δ (υ))

are positive for all

υ \geq υ_{1}

and are sufficiently large. From Lemma 4, we have three possible situations

(S_{1})

,

(S_{2})

or

(S_{3})

. Assume that

(S_{1})

holds. Using Lemma 1, we find that

w^{'} (υ) \geq \frac{θ}{2} υ^{2} w^{'''} (υ)

(13)

for every

θ \in (0, 1)

and for all large

υ

. Define

φ (υ) : = η (υ) (\frac{a (υ) {(w^{'''} (υ))}^{β}}{w^{β} (υ)}) .

(14)

We see that

φ (υ) > 0

for

υ \geq υ_{1},

where

η \in C^{1} ([υ_{0}, \infty), (0, \infty))

and

φ^{'} (υ) = η^{'} (υ) \frac{a (υ) {(w^{'''} (υ))}^{β}}{w^{β} (υ)} + η (υ) \frac{{(a {(w^{'''})}^{β})}^{'} (υ)}{w^{β} (υ)} - β η (υ) \frac{w^{β - 1} (υ) w^{'} (υ) a (υ) {(w^{'''} (υ))}^{β}}{w^{2 β} (υ)} .

Using (13) and (14), we obtain that

\begin{matrix} φ^{'} (υ) & \leq \frac{η^{'} (υ)}{η (υ)} φ (υ) + η (υ) \frac{{(a (υ) {(w^{'''} (υ))}^{β})}^{'}}{w^{β} (υ)} - β η (υ) \frac{θ}{2!} υ^{2} \frac{a (υ) {(w^{'''} (υ))}^{β + 1}}{w^{β + 1} (υ)} \\ \leq \frac{η^{'} (υ)}{η (υ)} φ (υ) + η (υ) \frac{{(a (υ) {(w^{'''} (υ))}^{β})}^{'}}{w^{β} (υ)} - \frac{β θ υ^{2}}{2 {(η (υ) a (υ))}^{\frac{1}{β}}} φ {(υ)}^{\frac{β + 1}{β}} . \end{matrix}

(15)

From (1) and (15), it follows that

φ^{'} (υ) \leq \frac{η^{'} (υ)}{η (υ)} φ (υ) - k η (υ) \frac{q (υ) w^{β} (δ (υ))}{w^{β} (υ)} - \frac{β θ υ^{2}}{2 {(η (υ) a (υ))}^{\frac{1}{β}}} φ {(υ)}^{\frac{β + 1}{β}} .

Note that

w^{'} (υ) > 0

and

δ (υ) \geq υ

. Thus, we find that

φ^{'} (υ) \leq \frac{η^{'} (υ)}{η (υ)} φ (υ) - k η (υ) q (υ) - \frac{β θ υ^{2}}{2 {(η (υ) a (υ))}^{\frac{1}{β}}} φ {(υ)}^{\frac{β + 1}{β}} .

(16)

Multiplying (16) by

H_{1} (υ, s)

and integrating the resulting inequality from

υ_{1}

to

υ

, we find that

\begin{matrix} \int_{υ_{1}}^{υ} H_{1} (υ, s) k η (s) q (s) d s & \leq & φ (υ_{1}) H_{1} (υ, υ_{1}) + \int_{υ_{1}}^{υ} (\frac{\partial}{\partial s} H_{1} (υ, s) + \frac{η^{'} (s)}{η (s)} H_{1} (υ, s)) φ (s) d s \\ - \int_{υ_{1}}^{υ} \frac{β θ s^{2}}{2! {(η (s) a (s))}^{\frac{1}{β}}} H_{1} (υ, s) φ^{\frac{β + 1}{β}} (s) d s . \end{matrix}

From (9), we obtain

\begin{matrix} \int_{υ_{1}}^{υ} H_{1} (υ, s) k η (s) q (s) d s & \leq & φ (υ_{1}) H_{1} (υ, υ_{1}) + \int_{υ_{1}}^{υ} h_{1} (υ, s) H_{1}^{β / (β + 1)} (υ, s) φ (s) d s \\ - \int_{υ_{1}}^{υ} \frac{β θ s^{2}}{2 {(η (s) a (s))}^{\frac{1}{β}}} H_{1} (υ, s) φ^{\frac{β + 1}{β}} (s) d s . \end{matrix}

(17)

Lemma 3 with

V = β θ s^{2} / (2 {(η (s) a (s))}^{\frac{1}{β}}) H_{1} (υ, s), U = h_{1} (υ, s) H_{1}^{β / (β + 1)} (υ, s)

, and

x = φ (s)

, tell us that

h_{1} (υ, s) H_{1}^{β / (β + 1)} (υ, s) φ (s) - \frac{β θ s^{2}}{2 {(η (s) a (s))}^{\frac{1}{β}}} H_{1} (υ, s) φ^{\frac{β + 1}{β}} (s) \leq \frac{h_{1}^{β + 1} (υ, s) H_{1}^{β} (υ, s)}{{(β + 1)}^{β + 1}} \frac{2^{β} η (s) a (s)}{{(θ s^{2})}^{β}},

which, with (17), gives

\frac{1}{H_{1} (υ, υ_{1})} \int_{υ_{1}}^{υ} (H_{1} (υ, s) k η (s) q (s) - π (s, υ)) d s \leq φ (υ_{1}),

contradicting (11). Now, let us assume that

(S_{2})

holds. Define

ψ (υ) : = ϑ (υ) \frac{w^{'} (υ)}{w (υ)} .

We see that

ψ (υ) > 0

for

υ \geq υ_{1},

where

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

. Differentiating

ψ (υ)

, we find

ψ^{'} (υ) = \frac{ϑ^{'} (υ)}{ϑ (υ)} ψ (υ) + ϑ (υ) \frac{w^{''} (υ)}{w (υ)} - \frac{1}{ϑ (υ)} ψ {(υ)}^{2} .

(18)

Integrating (1) from

υ

to m and using the fact that

w^{'} (υ) > 0

, we find that

a (m) {(w^{'''} (m))}^{β} - a (υ) {(w^{'''} (υ))}^{β} = - \int_{υ}^{m} q (s) g (w (δ (s))) d s .

By virtue of

w^{'} (υ) > 0

and

δ (υ) \geq υ

, we obtain

a (m) {(w^{'''} (m))}^{β} - a (υ) {(w^{'''} (υ))}^{β} \leq - k w^{β} (υ) \int_{υ}^{u} q (s) d s .

Letting

m \to \infty

, we see that

a (υ) {(w^{'''} (υ))}^{β} \geq k w^{β} (υ) \int_{υ}^{\infty} q (s) d s

and so

w^{'''} (υ) \geq w (υ) {(\frac{k}{a (υ)} \int_{υ}^{\infty} q (s) d s)}^{1 / β} .

Integrating again from

υ

to ∞, we obtain

w^{''} (υ) + w (υ) \int_{υ}^{\infty} {(\frac{k}{a (ς)} \int_{ς}^{\infty} q (s) d s)}^{1 / β} d ς \leq 0 .

(19)

From (18) and (19), we obtain that

ψ^{'} (υ) \leq \frac{ϑ^{'} (υ)}{ϑ (υ)} ψ (υ) - ϑ (υ) ϖ (s) - \frac{1}{ϑ (υ)} ψ {(υ)}^{2} .

(20)

Multiplying (20) by

H_{2} (υ, s)

and integrating the resulting inequality from

υ_{1}

to

υ

, it follows that

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

Thus, from (10), we obtain

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

and so

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

which contradicts (12). Finally, assume that

(S_{3})

holds and

lim_{υ \to \infty} w (υ) \neq 0

. Recalling that

a (υ) {(w^{'''} (υ))}^{β}

is non-increasing, we obtain that

a^{1 / β} (s) w^{'''} (s) \leq a^{1 / β} (υ) w^{'''} (υ), s \geq υ \geq υ_{1} .

Dividing the latter inequality by

a^{1 / β} (s)

and integrating the resulting inequality from

υ

to u, we find

w^{''} (u) \leq w^{''} (υ) + a^{1 / β} (υ) w^{'''} (υ) \int_{υ}^{u} a^{- 1 / β} (s) ds .

Letting

u \to \infty

, we obtain

0 \leq w^{''} (υ) + a^{1 / β} (υ) w^{'''} (υ) ζ (υ) .

Thus,

\frac{- a^{1 / β} (υ) w^{'''} (υ) ζ (υ)}{w^{''} (υ)} \leq 1 .

(21)

Furthermore, due to (21), we obtain that

{(\frac{w^{''} (υ)}{ζ (υ)})}^{'} \geq 0 .

(22)

Now define

ϕ (υ) : = \frac{a (υ) {(w^{'''} (υ))}^{β}}{{(w^{''} (υ))}^{β}} .

(23)

We see that

ϕ (υ) < 0

for

υ \geq υ_{1}

and

ϕ^{'} (υ) = \frac{{(a (υ) {(w^{'''} (υ))}^{β})}^{'}}{{(w^{''} (υ))}^{β}} - \frac{β a (υ) {(w^{'''} (υ))}^{β + 1}}{{(w^{''} (υ))}^{β + 1}} .

It follows from (1) and (21) that

ϕ^{'} (υ) = \frac{- k q (υ) w^{β} (δ (υ))}{{(w^{''} (υ))}^{β}} - \frac{β ϕ^{β / β + 1} (υ)}{a^{1 / β} (υ)} .

From Lemma 1, we find

w (υ) \geq \frac{θ_{1}}{2} υ^{2} w^{''} (υ) .

(24)

Thus, we have

ϕ^{'} (υ) = \frac{- k q (υ) w^{β} (δ (υ))}{{(w^{''} (δ (υ)))}^{β}} \frac{{(w^{''} (δ (υ)))}^{β}}{{(w^{''} (υ))}^{β}} - \frac{β ϕ^{β / β + 1} (υ)}{a^{1 / β} (υ)} .

From (24), we obtain

ϕ^{'} (υ) \leq - k q (υ) {(\frac{θ_{1} δ^{2} (υ)}{2})}^{β} {(\frac{ζ (δ (υ))}{ζ (υ)})}^{β} - \frac{β ϕ^{β / β + 1} (υ)}{a^{1 / β} (υ)} .

(25)

Using (21) and (23), we see, due to (26), that

- ϕ (υ) ζ^{β} (υ) \leq 1 .

(26)

Multiplying (26) by

ζ^{β} (υ)

and integrating the resulting inequality from

υ_{1}

to

υ

, we obtain

\begin{matrix} ζ^{β} (υ) ϕ (υ) - ζ^{β} (υ_{1}) ϕ (υ_{1}) + β \int_{υ_{1}}^{υ} a^{- 1 / β} (s) ζ^{β - 1} (s) ϕ (s) d s \\ \leq - \int_{υ_{1}}^{υ} k q (s) {(\frac{θ_{1} δ^{2} (s)}{2})}^{β} ζ^{β} (δ (s)) d s - β \int_{υ_{1}}^{υ} \frac{ϕ^{β / β + 1} (s)}{a^{1 / β} (s)} ζ^{β} (s) d s . \end{matrix}

(27)

Multiplying (27) by

H_{3} (υ, s)

, we find that

\begin{matrix} \int_{υ_{1}}^{υ} H_{3} (υ, s) k q (s) {(\frac{θ_{1} δ^{2} (s)}{2})}^{β} ζ^{β} (δ (s)) d s & \leq & ζ^{β} (υ_{1}) ϕ (υ_{1}) H_{3} (υ, υ_{1}) - ζ^{β} (υ) ϕ (υ) H_{3} (υ, υ_{1}) \\ + \int_{υ_{1}}^{υ} β a^{- 1 / β} (s) ζ^{β - 1} (s) ϕ (s) H_{3} (υ, s) d s \\ - \int_{υ_{1}}^{υ} \frac{β ϕ^{β / β + 1} (s)}{a^{1 / β} (s)} ζ^{β} (s) H_{3} (υ, s) d s . \end{matrix}

Using Lemma 3 with

V = ζ^{β} (s) H_{3} (υ, s) / a^{1 / β} (s)

,

U = a^{- 1 / β} (s) ζ^{β - 1} (s) H_{3} (υ, s)

, and

x = ϕ (s)

, we obtain

β a^{- 1 / β} (s) ζ^{β - 1} (s) ϕ (s) H_{3} (υ, s) - \frac{β ϕ^{β / β + 1} (s)}{a^{1 / β} (s)} ζ^{β} (s) H_{3} (υ, s) \leq \frac{β^{β + 1} H_{3} (υ, s)}{{(β + 1)}^{β + 1}} \frac{1}{a^{1 / β} (s) ζ (s)}

and easily find, due to (26), that

\frac{1}{H_{3} (υ, υ_{1})} \int_{υ_{1}}^{υ} (H_{3} (υ, s) k q (s) {(\frac{θ_{1} δ^{2} (s)}{2})}^{β} ζ^{β} (δ (s)) - \tilde{π} (s, υ)) d s \leq ζ^{β} (υ_{1}) ϕ (υ_{1}) + 1,

which contradicts (11). This completes the proof. □

With the help of our Theorem 1, we now prove a generalized Hille–Nehari-type oscillation criterion (cf. Corollary 1).

Theorem 2

(Generalized Hille–Nehari-type oscillation criterion for (1)). Under assumptions

A_{1}

–

A_{5}

, if the differential equations

{(\frac{2 a^{\frac{1}{β}} (υ)}{{(θ υ^{2})}^{β}} {(w^{'} (υ))}^{β})}^{'} + k q (υ) w^{β} (υ) = 0,

(28)

for every

θ \in (0, 1)

,

w^{''} (υ) + w (υ) \int_{υ}^{\infty} {(\frac{1}{a (ς)} \int_{ς}^{\infty} q (s) d s)}^{1 / β} d ς = 0

(29)

and

{(a (υ) {(w^{'} (υ))}^{β})}^{'} + w^{β} (υ) k q (υ) {(\frac{ζ (δ (υ))}{ζ (υ)})}^{β} {(\frac{θ_{1}}{2} δ^{2} (υ))}^{β} = 0,

(30)

for every

θ_{1} \in (0, 1)

, are oscillatory, then every solution of (1) is either oscillatory or satisfies

lim_{υ \to \infty} w (υ) = 0

.

Proof.

Assume the contrary, that w is a positive solution of (1). Then, we can suppose that

w (υ)

and

w (δ (υ))

are positive for all

υ \geq υ_{1}

sufficiently large. From Lemma 4, we have three possible cases

(S_{1})

,

(S_{2})

, or

(S_{3})

. Let situation

(S_{1})

hold. From Theorem 1, we obtain that (16) holds. If we set

η (υ) = k = 1

in (16), then we find

φ^{'} (υ) + \frac{β θ υ^{2}}{2 a^{\frac{1}{β}} (υ)} φ {(υ)}^{\frac{β + 1}{β}} + q (υ) \leq 0 .

Thus, we can see that Equation (28) is nonoscillatory, which is a contradiction. Let case

(S_{2})

holds. From Theorem 1, we obtain that (20) holds. If we now set

ϑ (υ) = k = 1

in (20), then we obtain

ψ^{'} (υ) + ψ^{2} (υ) + ϖ (s) ς \leq 0 .

Hence, we see that Equation (29) is nonoscillatory, which is a contradiction. Let case

(S_{3})

hold and

lim_{υ \to \infty} w (υ) \neq 0

. From Theorem 1, we obtain that (25) holds. Thus, we see that

ϕ^{'} (υ) + \frac{β ϕ^{β / β + 1} (υ)}{a^{1 / β} (υ)} + k q (υ) {(\frac{θ_{1} δ^{2} (υ)}{2})}^{β} {(\frac{ζ (δ (υ))}{ζ (υ)})}^{β} \leq 0

and it follows that Equation (30) is nonoscillatory, which is a contradiction. Theorem 2 is proved. □

Let us now restrict ourselves to the case when

β = 1

. Note that, if

\int_{υ_{0}}^{\infty} \frac{1}{a (υ)} d υ < \infty

and

\underset{υ \to \infty}{lim inf} {(\int_{υ_{0}}^{υ} \frac{1}{a (s)} d s)}^{- 1} \int_{υ}^{\infty} {(\int_{υ_{0}}^{υ} \frac{1}{a (s)} d s)}^{2} q (s) d s > \frac{1}{4},

then Equation (8) with

β = 1

is oscillatory [14]. For

β = 1

our Theorem 2 gives a Hille–Nehari-type oscillation criterion.

Corollary 1

(Hille–Nehari-type oscillation criterion). Let

β = 1

. Under assumptions

A_{1}

–

A_{5}

with

k = 1

, if

\int_{υ_{0}}^{\infty} \frac{θ υ^{2}}{2 a (υ)} d υ < \infty

and

\underset{υ \to \infty}{lim inf} {(\int_{υ_{0}}^{υ} \frac{θ s^{2}}{2 a (s)} d s)}^{- 1} \int_{υ}^{\infty} {(\int_{υ_{0}}^{υ} \frac{θ s^{2}}{2 a (s)} d s)}^{2} q (s) d s > \frac{1}{4}

(31)

for every constant

θ \in (0, 1)

,

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

(32)

and

\underset{υ \to \infty}{lim inf} {(\int_{υ_{0}}^{υ} \frac{1}{a (s)} d s)}^{- 1} \int_{υ}^{\infty} {(\int_{υ_{0}}^{υ} \frac{1}{a (s)} d s)}^{2} \frac{θ_{1} ζ (δ (s)) δ^{2} (s) q (s)}{2 ζ (s)} d s > \frac{1}{4}

(33)

for every constant

θ_{1} \in (0, 1)

, then every solution of (1) is either oscillatory or satisfies

lim_{υ \to \infty} w (υ) = 0

.

The next section shows that our results are new even in the very special situation covered by Corollary 1.

4. Illustrative Examples

We give two examples for which all results of [17,18] cannot be applied, since

δ (υ) = υ + 1 > υ

, while our Hille–Nehari-type oscillation criterion holds.

Example 1.

Let us consider the following equation:

{(e^{υ} w^{'''} (υ))}^{'} + \frac{1}{16} e^{υ + \frac{1}{2}} w (υ + 1) = 0, υ \geq 1,

(34)

where

α > 0

is a constant. Note that

β = 1, a (υ) = e^{υ}, q (υ) = e^{υ + \frac{1}{2}} / 16

and

δ (υ) = υ + 1

. It is easy to see that all conditions of our Corollary 1 are satisfied. Hence, all solutions of (34) are either oscillatory or satisfy

lim_{υ \to \infty} w (υ) = 0

.

Following is a second example, where previous results in the literature cannot be applied, while our Corollary 1 is conclusive.

Example 2.

Consider the following equation:

{(υ^{4} w^{'''} (υ))}^{'} + α w (υ + 1) = 0, υ \geq 1,

(35)

where

α > 0

is a constant. Note that

β = 1, a (υ) = υ^{4}, q (υ) = α

, and

δ (υ) = υ + 1

. If we set

k = 1

, then condition (31) becomes

\begin{matrix} \underset{υ \to \infty}{lim inf} & {(\int_{υ_{0}}^{υ} \frac{θ s^{2}}{2 a (s)} d s)}^{- 1} \int_{υ}^{\infty} {(\int_{υ_{0}}^{υ} \frac{θ s^{2}}{2 a (s)} d s)}^{2} q (s) d s \\ = \underset{υ \to \infty}{lim inf} (2 υ) \int_{υ}^{\infty} \frac{α}{4 s^{2}} d s = \underset{υ \to \infty}{lim inf} (2 υ) (\frac{α}{4 υ}) \\ = \frac{α}{2} > \frac{1}{4}, \end{matrix}

condition (32) becomes

\begin{matrix} \underset{υ \to \infty}{lim inf} υ \int_{υ_{0}}^{υ} \int_{v}^{υ} (\frac{1}{a (ς)} \int_{ς}^{υ} q (s) d s) d ς d v & = & \underset{υ \to \infty}{lim inf} υ (\frac{α}{2 υ}) \\ = & \frac{α}{2} > \frac{1}{4}, \end{matrix}

and (33) is satisfied. Therefore, from Corollary 1, any solution of Equation (35) is either oscillatory, if

α > 0.5

, or satisfies

lim_{υ \to \infty} w (υ) = 0

.

5. Conclusions and Future Work

In this work, we obtained new Philos-type and Hille–Nehari-type oscillation criteria for equations of form (1). Our results are easy to generalize for the following equations:

{(a (υ) {(w^{'''} (υ))}^{β})}^{'} + \sum_{i = 1}^{j} q_{i} (υ) w^{α} (δ_{i} (υ)) = 0, j \geq 1,

(36)

where

υ \geq υ_{0}

,

δ_{i} (υ) \leq υ

,

α \leq β

, and

α

and

β

are ratios of odd positive integers. However, it is not easy to find analogous results for Equation (36) in the case

α > β

. We leave this as an interesting open question.

Author Contributions

Conceptualization, O.B., A.H.A., F.M. and Y.N.R.; methodology, O.B., A.H.A., F.M. and Y.N.R.; software, O.B., A.H.A., F.M. and Y.N.R.; validation, O.B., A.H.A., F.M. and Y.N.R.; formal analysis, O.B., A.H.A., F.M. and Y.N.R.; investigation, O.B., A.H.A., F.M. and Y.N.R.; re-sources, O.B., A.H.A., F.M. and Y.N.R.; data curation, O.B., A.H.A., F.M. and Y.N.R.; writing—original draft preparation, O.B., A.H.A., F.M. and Y.N.R.; writing—review and editing, O.B., A.H.A., F.M. and Y.N.R.; visualization, O.B., A.H.A., F.M. and Y.N.R.; funding acquisition, O.B., A.H.A., F.M. and Y.N.R. All authors have read and agreed to the published version of the manuscript.

Funding

Princess Nourah bint Abdulrahman University Researchers Supporting Project number (PNURSP2022R27), Princess Nourah bint Abdulrahman University, Riyadh, Saudi Arabia.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Acknowledgments

The research is supported by Princess Nourah bint Abdulrahman University, Riyadh, Saudi Arabia. Researchers Supporting Project number: PNURSP2022R27.

Conflicts of Interest

The authors declear no conflict of interest.

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Bazighifan, O.; Ali, A.H.; Mofarreh, F.; Raffoul, Y.N. Extended Approach to the Asymptotic Behavior and Symmetric Solutions of Advanced Differential Equations. Symmetry 2022, 14, 686. https://doi.org/10.3390/sym14040686

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Bazighifan O, Ali AH, Mofarreh F, Raffoul YN. Extended Approach to the Asymptotic Behavior and Symmetric Solutions of Advanced Differential Equations. Symmetry. 2022; 14(4):686. https://doi.org/10.3390/sym14040686

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Bazighifan, Omar, Ali Hasan Ali, Fatemah Mofarreh, and Youssef N. Raffoul. 2022. "Extended Approach to the Asymptotic Behavior and Symmetric Solutions of Advanced Differential Equations" Symmetry 14, no. 4: 686. https://doi.org/10.3390/sym14040686

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Extended Approach to the Asymptotic Behavior and Symmetric Solutions of Advanced Differential Equations

Abstract

1. Introduction

2. Hypotheses and Preliminaries

3. Main Results

4. Illustrative Examples

5. Conclusions and Future Work

Author Contributions

Funding

Institutional Review Board Statement

Informed Consent Statement

Data Availability Statement

Acknowledgments

Conflicts of Interest

References

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