Symmetry and Its Importance in the Oscillation of Solutions of Differential Equations

AlGhamdi, Ahmed; Cesarano, Clemente; Almarri, Barakah; Bazighifan, Omar

doi:10.3390/sym13040650

Open AccessArticle

Symmetry and Its Importance in the Oscillation of Solutions of Differential Equations

¹

Department of Computer Engineering, College of Computers and Information Technology, Taif University, Taif 21944, Saudi Arabia

²

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

³

Mathematical Science Department, Faculty of Science, Princess Nourah Bint Abdulrahman University, Riyadh 11564, Saudi Arabia

⁴

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 2021, 13(4), 650; https://doi.org/10.3390/sym13040650

Submission received: 18 March 2021 / Revised: 5 April 2021 / Accepted: 9 April 2021 / Published: 12 April 2021

(This article belongs to the Section Mathematics)

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Abstract

:

Oscillation and symmetry play an important role in many applications such as engineering, physics, medicine, and vibration in flight. The purpose of this article is to explore the oscillation of fourth-order differential equations with delay arguments. New Kamenev-type oscillatory properties are established, which are based on a suitable Riccati method to reduce the main equation into a first-order inequality. Our new results extend and simplify existing results in the previous studies. Examples are presented in order to clarify the main results.

Keywords:

delay differential equations; fourth-order; oscillation

1. Introduction

Fourth-order differential equations have enormous potential for applications in engineering, medicine, aviation, physics, etc. In past years, significant attention has been devoted to the oscillation theory of various classes of equations, see [1,2,3,4,5,6,7,8,9].

In this work, we are concerned with the fourth-order delay differential equation:

{(j_{3} (y) {(j_{2} (y) {(j_{1} (y) ξ^{'} (y))}^{'})}^{'})}^{'} + \sum_{r = 1}^{m} π_{r} (y) f (ξ (z_{r} (y))) = 0, y \geq y_{0} .

(1)

Throughout this article, we suppose that

(H₁): $π_{r} \in C ([y_{0}, \infty), R)$ is non-negative, $r = 1, 2, . . ., m, z_{r} \in C^{1} ([y_{0}, \infty), R), z_{r} (y) \leq y$ and $lim_{y \to \infty} z_{r} (y) = \infty, f \in C (R, R),$ and there exists a constant $k > 0$ such that $f (u) / u \geq k$ , for $u \neq 0 .$
(H₂): $j_{i} \in C^{3} ([y_{0}, \infty), R), i = 1, 2, 3$ are positive and

$\int_{y_{0}}^{\infty} \frac{1}{j_{i} (s)} d s = \infty .$

(2)

Delay differential equations can also be used in engineering and the modeling of dynamical networks of interacting free-bodies. Finally, the properties of delay differential equations are used in the study of singular differential equations of fractions, see [10,11,12,13,14].

It is clear that the form of problem Equation (1) is more general than all the problems considered in [12,14], where the authors in [12,14] discussed the oscillatory properties of differential equations of the neutral type with a canonical operator, and they used the comparison method and integral averaging technique to obtain these properties. Their approach is based on using these mentioned methods to reduce Equation (1) into a second-order equation, while in our article we discuss the oscillatory properties of differential equations with a middle term and with a non-canonical operator of the delay-type, and we employ a different approach based on using the Riccati technique to reduce the main equation into a first-order inequality to obtain more effective Kamenev-type oscillatory properties.

The aim of this article is to establish the oscillatory properties of Equation (1).

Several studies have had very interesting results related to the oscillatory properties of solutions of differential equations.

Dzurina et al. [15] obtained sufficient conditions for oscillation for equation

{(j_{3} (y) {(j_{2} (y) {(j_{1} (y) ξ^{'} (y))}^{'})}^{'})}^{'} + p (y) ξ^{'} (y) + π (y) ξ (τ (y)) = 0 .

(3)

They also used the technique of comparison.

In Grace et al. [16], some comparison criteria have been studied when

τ (y) \leq y,

and some oscillation criteria for Equation (1) are given when Equation (2) holds.

In addition, the results obtained in [17] are presented for Equation (1) when

lim_{y \to \infty} inf \int_{y_{1}}^{y} \frac{1}{j_{1} (s)} (\int_{y_{1}}^{y} \frac{1}{j_{2} (u)} \int_{u}^{\infty} \frac{1}{j_{3} (v)} \int_{v}^{\infty} A_{1} (υ) d υ d v d u) d s > \frac{1}{4}

(4)

and

lim_{y \to \infty} inf (\int_{y_{1}}^{y} (\int_{y_{1}}^{y} \frac{d v}{j_{2} (v)} \int_{y_{1}}^{v} \frac{d s}{j_{3} (s)}) \frac{1}{j_{1} (s)} d s) \int_{y_{1}}^{\infty} A_{2} (υ) d υ > \frac{1}{4} for y \geq y_{1},

(5)

where there are positive functions

A_{1}, A_{2} \in C^{1} ([y_{0}, \infty), R^{+}) .

The purpose of this article is to explore the oscillation of Equation (1). New oscillation theorems are established, which are based on a suitable Riccati-type method.

This article is organized as follows. In Section 2, we introduce some auxiliary lemmas and some notations. In Section 3, we present new oscillation results for Equation (1) by Riccati transformation. Finally, two examples with specific values of parameters are offered to illustrate our main theorems.

2. Some Lemmas

We start with the following important Lemmas.

Lemma 1.

[18] Let

α \geq 1

,

C > 0

and D be constant. Then

D ξ - C ξ^{(α + 1) / α} \leq \frac{α^{α}}{{(α + 1)}^{α + 1}} \frac{D^{α + 1}}{C^{α}},

(6)

for all positive ξ.

Lemma 2.

[19] If the function ξ satisfies

ξ^{(m)} (y) > 0,

m = 0, 1, . . ., n,

and

ξ^{(n + 1)} (y) < 0

for

y \geq y_{0},

then

\frac{ξ (y)}{y^{n} / n!} \geq \frac{ξ^{'} (y)}{y^{n - 1} / (n - 1)!} .

(7)

Lemma 3.

[17] Let ξ be an eventually positive solution of Equation (1).

Then, we find the following cases:

\begin{matrix} (N_{1}) & ξ^{'} (y) > 0, {(j_{1} ξ^{'})}^{'} (y) > 0, {(j_{2} {(j_{1} ξ^{'})}^{'})}^{'} (y) > 0, {(j_{3} {(j_{2} {(j_{1} ξ^{'})}^{'})}^{'})}^{'} (y) < 0, \end{matrix}

(8)

\begin{matrix} (N_{2}) & ξ^{'} (y) > 0, {(j_{1} ξ^{'})}^{'} (y) < 0, {(j_{2} {(j_{1} ξ^{'})}^{'})}^{'} (y) > 0, {(j_{3} {(j_{2} {(j_{1} ξ^{'})}^{'})}^{'})}^{'} (y) < 0 . \end{matrix}

(9)

For convenience, we introduce some notations:

\begin{matrix} δ (y) & : & = \int_{y_{1}}^{y} \frac{d s}{j_{3} (s)}, \end{matrix}

(10)

\begin{matrix} σ (y) & : & = \int_{y_{2}}^{y} \frac{δ (s) d s}{j_{2} (s)}, \end{matrix}

(11)

\begin{matrix} B (y) & : & = \frac{θ_{2} (y)}{j_{2} (y)} \int_{y}^{\infty} [\frac{1}{j_{3} (s)} \int_{s}^{\infty} k \sum_{r = 1}^{m} π_{r} (ν) (\frac{z_{r}^{3} (ν)}{ν^{3}}) d ν] d s \end{matrix}

(12)

and

A (y) : = \frac{1}{δ (y) σ (z_{r} (y))} (\int_{y_{3}}^{z (y)} \frac{σ (s) d s}{j_{1} (s)}) (\int_{y_{2}}^{z (y)} \frac{δ (s) d s}{j_{2} (s)}) .

(13)

3. Oscillation Criteria

In this section, we will give new oscillation criteria for Equation (1) by the Riccati technique.

Lemma 4.

Let ξ be an eventually positive solution of Equation (1) hold. If

(N_{1})

holds and there exists a function

θ_{1} \in C^{1} ([y_{0}, \infty), R^{+})

such that

ζ (y) : = θ_{1} (y) (\frac{j_{3} {(j_{2} {(j_{1} ξ^{'})}^{'})}^{'} (y)}{(j_{2} {(j_{1} ξ^{'})}^{'}) (y)}) > 0,

(14)

then

ζ^{'} (y) \leq - k θ_{1} (y) \sum_{r = 1}^{m} π_{r} (y) A (y) + \frac{j_{3} (y) {(θ_{1}^{'} (y))}^{2}}{2 θ_{1} (y)},

(15)

In addition, if

(N_{2})

holds and there exists a function

θ_{2} \in C^{1} ([y_{0}, \infty), R^{+})

such that

w (y) : = θ_{2} (y) (\frac{(j_{1} ξ^{'}) (y)}{ξ (y)}) > 0,

(16)

then

w^{'} (y) \leq - B (y) + \frac{j_{1} (y) {(θ_{2}^{'} (y))}^{2}}{4 θ_{2} (y)},

(17)

where

ζ (y)

and

w (y)

are called Riccati transformations.

Proof.

Let

ξ

be an eventually positive solution of Equation (1) hold. From Lemma 3 there exist two possible cases

(N_{1})

and

(N_{2})

.

Let case

(N_{1})

hold. From

{(j_{1} ξ^{'})}^{'} (y) > 0

and

{(j_{3} {(j_{2} {(j_{1} ξ^{'})}^{'})}^{'})}^{'} (y) < 0

for

y \geq y_{1}

, we obtain

\begin{matrix} (j_{2} {(j_{1} ξ^{'})}^{'}) (y) & = & (j_{2} {(j_{1} ξ^{'})}^{'}) (y_{1}) + \int_{y_{1}}^{y} \frac{j_{3} (s) {(j_{2} {(j_{1} ξ^{'})}^{'})}^{'} (s)}{j_{3} (s)} d s \\ \geq & j_{3} (y) (\int_{y_{1}}^{y} \frac{d s}{j_{3} (s)}) {(j_{2} {(j_{1} ξ^{'})}^{'})}^{'} (y) . \end{matrix}

(18)

Thus for

y \geq y_{1}

, we have

\begin{matrix} {(\frac{(j_{2} {(j_{1} ξ^{'})}^{'}) (y)}{δ (y)})}^{'} & = & \frac{{(j_{2} {(j_{1} ξ^{'})}^{'})}^{'} (y) δ (y) - (j_{2} {(j_{1} ξ^{'})}^{'}) (y) δ^{'} (y)}{δ^{2} (y)} \\ = & \frac{{(j_{2} {(j_{1} ξ^{'})}^{'})}^{'} (y)}{δ (y)} - \frac{(j_{2} {(j_{1} ξ^{'})}^{'}) (y) δ^{'} (y)}{δ^{2} (y)} \\ \leq & \frac{(j_{2} {(j_{1} ξ^{'})}^{'}) (y)}{δ^{2} (y)} [\frac{δ (y)}{j_{3} (y) \int_{y_{1}}^{y} \frac{d s}{j_{3} (s)}} - δ^{'} (y)] \\ \leq & 0 . \end{matrix}

(19)

Therefore,

(j_{2} {(j_{1} ξ^{'})}^{'}) (y) / δ (y)

is a non-increasing function for

y_{2} \geq y_{1}, y \geq y_{2}

. Then, we get

\begin{matrix} (j_{1} ξ^{'}) (y) & = & (j_{1} ξ^{'}) (y_{2}) + \int_{y_{2}}^{y} \frac{j_{2} (s) {(j_{1} ξ^{'})}^{'} (s) δ (s)}{j_{2} (s) δ (s)} d s \\ \geq & \frac{j_{2} (y)}{δ (y)} (\int_{y_{2}}^{y} \frac{δ (s) d s}{j_{2} (s)}) {(j_{1} ξ^{'})}^{'} (y) . \end{matrix}

(20)

Thus, from Equation (20), we obtain

\begin{matrix} {(\frac{(j_{1} ξ^{'}) (y)}{σ (y)})}^{'} & = & \frac{{(j_{1} ξ^{'})}^{'} (y) σ (y) - (j_{1} ξ^{'}) (y) σ^{'} (y)}{σ^{2} (y)} \\ = & \frac{{(j_{1} ξ^{'})}^{'} (y)}{σ (y)} - \frac{(j_{1} ξ^{'}) (y) σ^{'} (y)}{σ^{2} (y)} \\ \leq & \frac{(j_{1} ξ^{'}) (y)}{σ^{2} (y)} [\frac{σ (y)}{\frac{j_{2} (y)}{δ (y)} \int_{y_{2}}^{y} \frac{δ (s) d s}{j_{2} (s)}} - σ^{'} (y)] \\ \leq & 0 . \end{matrix}

(21)

Therefore,

((j_{1} ξ^{'}) (y)) / σ (y)

is a non-increasing function for

y_{3} \geq y_{2}, y \geq y_{3}

. So we get

\begin{matrix} ξ (y) & = & ξ (y_{3}) + \int_{y_{3}}^{y} \frac{(j_{1} ξ^{'}) (s) σ (s)}{j_{1} (s) σ (s)} d s \\ \geq & \frac{j_{1} (y)}{σ (y)} (\int_{y_{3}}^{y} \frac{σ (s) d s}{j_{1} (s)}) ξ^{'} (y) . \end{matrix}

(22)

From Equation (1), we have

{(j_{3} (y) {(j_{2} (y) {(j_{1} (y) ξ^{'} (y))}^{'})}^{'})}^{'} \leq - \sum_{r = 1}^{m} π_{r} (y) f (ξ (z_{r} (y))) .

(23)

By using condition

f (u) / u \geq k

, we see that

{(j_{3} (y) {(j_{2} (y) {(j_{1} (y) ξ^{'} (y))}^{'})}^{'})}^{'} \leq - k \sum_{r = 1}^{m} π_{r} (y) ξ (z_{r} (y)) .

(24)

Since

((j_{2} {(j_{1} ξ^{'})}^{'}) (y)) / δ (y)

is non-increasing, we get

\frac{(j_{2} {(j_{1} ξ^{'})}^{'}) (z_{r} (y))}{δ (z_{r} (y))} \geq \frac{(j_{2} {(j_{1} ξ^{'})}^{'}) (y)}{δ (y)}, z_{r} (y) \leq y,

(25)

i.e.,

\frac{{(j_{1} ξ^{'})}^{'} (z_{r} (y))}{{(j_{1} ξ^{'})}^{'} (y)} \geq \frac{j_{2} (y) δ (z_{r} (y))}{j_{2} (z_{r} (y)) δ (y)} .

(26)

Thus, from Equations (20), (22) and (26), we have

\begin{matrix} \frac{ξ (z_{r} (y))}{(j_{2} {(j_{1} ξ^{'})}^{'}) (y)} & = & \frac{1}{j_{2} (y)} \frac{ξ (z_{r} (y))}{ξ^{'} (z_{r} (y))} \frac{ξ^{'} (z_{r} (y))}{{(j_{1} ξ^{'})}^{'} (z_{r} (y))} \frac{{(j_{1} ξ^{'})}^{'} (z_{r} (y))}{{(j_{1} ξ^{'})}^{'} (y)} \\ \geq & \frac{1}{j_{2} (y)} \frac{j_{1} (z_{r} (y))}{σ (z_{r} (y))} (\int_{y_{3}}^{z (y)} \frac{σ (s) d s}{j_{1} (s)}) (\frac{j_{2}}{j_{1} δ}) \\ (z_{r} (y)) (\int_{y_{2}}^{z (y)} \frac{δ (s) d s}{j_{2} (s)}) \frac{j_{2} (y) δ (z_{r} (y))}{j_{2} (z_{r} (y)) δ (y)} . \end{matrix}

Thus,

\frac{ξ (z_{r} (y))}{(j_{2} {(j_{1} ξ^{'})}^{'}) (y)} \geq \frac{1}{δ (y) σ (z_{r} (y))} (\int_{y_{3}}^{z (y)} \frac{σ (s) d s}{j_{1} (s)}) (\int_{y_{2}}^{z (y)} \frac{δ (s) d s}{j_{2} (s)}) .

(27)

From

ζ (y)

, we obtain

\begin{matrix} ζ^{'} (y) & = & θ_{1}^{'} (y) [\frac{j_{3} {(j_{2} {(j_{1} ξ^{'})}^{'})}^{'} (y)}{(j_{2} {(j_{1} ξ^{'})}^{'}) (y)}] + θ_{1} (y) \frac{{(j_{3} {(j_{2} {(j_{1} ξ^{'})}^{'})}^{'})}^{'} (y)}{(j_{2} {(j_{1} ξ^{'})}^{'}) (y)} \\ - θ_{1} (y) \frac{j_{3} {(j_{2} {(j_{1} ξ^{'})}^{'})}^{'} (y) {(j_{2} {(j_{1} ξ^{'})}^{'})}^{'} (y)}{{(j_{2} {(j_{1} ξ^{'})}^{'})}^{2} (y)} . \end{matrix}

Using Equations (14), (24) and (27), we obtain

ζ^{'} (y) \leq \frac{θ_{1}^{'} (y)}{θ_{1} (y)} ζ (y) - k θ_{1} (y) \sum_{r = 1}^{m} π_{r} (y) \frac{ξ (z_{r} (y))}{(j_{2} {(j_{1} ξ^{'})}^{'}) (y)} - \frac{1}{j_{3} (y) θ_{1} (y)} ζ^{2} (y),

(28)

which yields

ζ^{'} (y) \leq - k θ_{1} (y) \sum_{r = 1}^{m} π_{r} (y) A (y) + \frac{θ_{1}^{'} (y)}{θ_{1} (y)} ζ (y) - \frac{1}{j_{3} (y) θ_{1} (y)} ζ^{2} (y) .

(29)

Using Lemma 1 with

C = 1 / (j_{3} (y) θ_{1} (y)), D = θ_{1}^{'} (y) / θ_{1} (y)

and

ξ = ζ (y)

, we get

\frac{θ_{1}^{'} (y)}{θ_{1} (y)} ζ (y) - \frac{1}{j_{3} (y) θ_{1} (y)} ζ^{2} (y) \leq \frac{j_{3} (y) {(θ_{1}^{'} (y))}^{2}}{2 θ_{1} (y)} .

(30)

From Equations (29) and (30), we get

ζ^{'} (y) \leq - k θ_{1} (y) \sum_{r = 1}^{m} π_{r} (y) A (y) + \frac{j_{3} (y) {(θ_{1}^{'} (y))}^{2}}{2 θ_{1} (y)} .

(31)

Thus, Equation (15) holds.

Let case

(N_{2})

hold. From

w (y)

, we find that

w^{'} (y) = θ_{2}^{'} (y) \frac{(j_{1} ξ^{'}) (y)}{ξ (y)} + θ_{2} (y) \frac{{(j_{1} ξ^{'})}^{'} (y)}{ξ (y)} - θ_{2} (y) \frac{(j_{1} {(ξ^{'})}^{2}) (y)}{ξ^{2} (y)} .

(32)

Hence by Equation (16), we get

w^{'} (y) = \frac{θ_{2}^{'} (y)}{θ_{2} (y)} w (y) + θ_{2} (y) \frac{{(j_{1} ξ^{'})}^{'} (y)}{ξ (y)} - \frac{w^{2} (y)}{j_{1} (y) θ_{2} (y)} .

(33)

From Lemma 2, we find

ξ (y) \geq \frac{y}{3} ξ^{'} (y), where n = 3 .

(34)

Integrating Equation (34) from

z_{r} (y)

to

y,

we obtain

\frac{ξ (z_{r} (y))}{ξ (y)} \geq \frac{z_{r}^{3} (y)}{y^{3}} .

(35)

Integrating Equation (1) from y to

u,

we obtain

(j_{3} {(j_{2} {(j_{1} ξ^{'})}^{'})}^{'}) (u) - (j_{3} {(j_{2} {(j_{1} ξ^{'})}^{'})}^{'}) (y) + \int_{y}^{u} \sum_{r = 1}^{m} π_{r} (s) f (ξ (z_{r} (s))) d s \leq 0 .

(36)

Easily we find that

(j_{3} {(j_{2} {(j_{1} ξ^{'})}^{'})}^{'}) (u) - (j_{3} {(j_{2} {(j_{1} ξ^{'})}^{'})}^{'}) (y) + \int_{y}^{u} k \sum_{r = 1}^{m} π_{r} (s) ξ (z_{r} (s)) d s \leq 0 .

(37)

From

ξ^{'} (y) > 0

and Equation (35), we have

(j_{3} {(j_{2} {(j_{1} ξ^{'})}^{'})}^{'}) (u) - (j_{3} {(j_{2} {(j_{1} ξ^{'})}^{'})}^{'}) (y) + ξ (y) \int_{y}^{u} k \sum_{r = 1}^{m} π_{r} (s) (\frac{z_{r}^{3} (s)}{s^{3}}) d s \leq 0 .

(38)

Letting

u \to \infty

, we arrive at the inequality

- (j_{3} {(j_{2} {(j_{1} ξ^{'})}^{'})}^{'}) (y) + ξ (y) \int_{y}^{\infty} k \sum_{r = 1}^{m} π_{r} (s) (\frac{z_{r}^{3} (s)}{s^{3}}) d s \leq 0 .

(39)

Thus,

{(j_{2} {(j_{1} ξ^{'})}^{'})}^{'} (y) \geq ξ (y) [\frac{1}{j_{3} (s)} \int_{y}^{\infty} k \sum_{r = 1}^{m} π_{r} (s) (\frac{z_{r}^{3} (s)}{s^{3}}) d s] .

(40)

Integrating Equation (40) from y to ∞ we obtain

{(j_{1} ξ^{'})}^{'} (y) + ξ (y) \frac{1}{j_{2} (y)} \int_{y}^{\infty} [\frac{1}{j_{3} (s)} \int_{s}^{\infty} k \sum_{r = 1}^{m} π_{r} (ν) (\frac{z_{r}^{3} (ν)}{ν^{3}}) d ν] d s \leq 0 .

(41)

Hence, by Equation (41) in Equation (33), we find

w^{'} (y) \leq - B (y) + \frac{θ_{2}^{'} (y)}{θ_{2} (y)} w (y) - \frac{w^{2} (y)}{j_{1} (y) θ_{2} (y)} .

(42)

Thus, we have

w^{'} (y) \leq - B (y) + \frac{j_{1} (y) {(θ_{2}^{'} (y))}^{2}}{4 θ_{2} (y)} .

(43)

Thus, Equation (17) holds. This completes the proof. □

In the next theorem, we establish new Kamenev-type oscillatory properties for Equation (1).

Theorem 1.

Let Equation (2) hold. Assume that there exist positive functions

θ_{1}, θ_{2}, δ, σ \in C^{1} ([y_{0}, \infty))

and an integer

n \in N .

If

\underset{y \to \infty}{lim sup} \frac{1}{y^{n}} \int_{y_{0}}^{y} {(y - s)}^{n} (k θ_{1} (s) \sum_{r = 1}^{m} π_{r} (s) A (s) - \frac{j_{3} (s) {(θ_{1}^{'} (s))}^{2}}{2 θ_{1} (s)}) d s = \infty

(44)

and

\underset{y \to \infty}{lim sup} \frac{1}{y^{n}} \int_{y_{0}}^{y} {(y - s)}^{n} (B (s) - \frac{j_{1} (s) {(θ_{2}^{'} (s))}^{2}}{4 θ_{2} (s)}) d s = \infty,

(45)

then Equation (1) is oscillatory.

Proof.

Let

ξ

be a non-oscillatory solution of Equation (1). Without loss of generality, we can assume that

ξ (y)

is eventually positive. For case

(N_{1})

, from Lemma 4, we get that Equation (15) holds. Thus, we have

- \int_{y_{0}}^{y} {(y - s)}^{n} ζ^{'} (s) d s \geq \int_{y_{0}}^{y} {(y - s)}^{n} (k θ_{1} (s) \sum_{r = 1}^{m} π_{r} (s) A (s) - \frac{j_{3} (s) {(θ_{1}^{'} (s))}^{2}}{2 θ_{1} (s)}) d s .

(46)

Since

\int_{y_{0}}^{y} {(y - s)}^{n} ζ^{'} (s) d s = n \int_{y_{0}}^{y} {(y - s)}^{n - 1} ζ (s) d s - {(y - y_{0})}^{n} ζ (y_{0}) .

(47)

Thus, we get

\begin{matrix} {(\frac{y - y_{0}}{y})}^{n} ζ (y_{0}) - \frac{n}{y^{n}} \int_{y_{0}}^{y} {(y - s)}^{n - 1} ζ (s) d s \\ \geq & \frac{1}{y^{n}} \int_{y_{0}}^{y} {(y - s)}^{n} (k θ_{1} (s) \sum_{r = 1}^{m} π_{r} (s) A (s) - \frac{j_{3} (s) {(θ_{1}^{'} (s))}^{2}}{2 θ_{1} (s)}) d s . \end{matrix}

Hence,

\frac{1}{y^{n}} \int_{y_{0}}^{y} {(y - s)}^{n} (k θ_{1} (s) \sum_{r = 1}^{m} π_{r} (s) A (s) - \frac{j_{3} (s) {(θ_{1}^{'} (s))}^{2}}{2 θ_{1} (s)}) d s \leq {(\frac{y - y_{0}}{y})}^{n} ζ (y_{0}),

(48)

and so

\underset{y \to \infty}{lim sup} \frac{1}{y^{n}} \int_{y_{0}}^{y} {(y - s)}^{n} (k θ_{1} (s) \sum_{r = 1}^{m} π_{r} (s) A (s) - \frac{j_{3} (s) {(θ_{1}^{'} (s))}^{2}}{2 θ_{1} (s)}) d s \leq ζ (y_{0}),

(49)

which contradicts Equation (44).

For case

(N_{2})

, from Lemma 4, we find Equation (17) holds. Thus, we see

- \int_{y_{0}}^{y} {(y - s)}^{n} w^{'} (s) d s \geq \int_{y_{0}}^{y} {(y - s)}^{n} (B (y) - \frac{j_{1} (y) {(θ_{2}^{'} (y))}^{2}}{4 θ_{2} (y)}) d s .

(50)

From Equations (47) and (50), we get

\begin{matrix} {(\frac{y - y_{0}}{y})}^{n} w (y_{0}) - \frac{n}{y^{n}} \int_{y_{0}}^{y} {(y - s)}^{n - 1} w (s) d s \\ \geq & \frac{1}{y^{n}} \int_{y_{0}}^{y} {(y - s)}^{n} (B (s) - \frac{j_{1} (s) {(θ_{2}^{'} (s))}^{2}}{4 θ_{2} (s)}) d s, \end{matrix}

which yields

\underset{y \to \infty}{lim sup} \frac{1}{y^{n}} \int_{y_{0}}^{y} {(y - s)}^{n} (B (s) - \frac{j_{1} (s) {(θ_{2}^{'} (s))}^{2}}{4 θ_{2} (s)}) d s \leq w (y_{0}),

(51)

which contradicts Equation (45).

Theorem 1 has been proved. □

Now, we give some interesting examples to demonstrate the applicability of the obtained criteria in the main results.

Example 1.

Consider a differential equation

{(y {(y {(y ξ^{'} (y))}^{'})}^{'})}^{'} + y ξ (a y) = 0, y \geq 1,

(52)

where

a \in (0, 1)

is a constant. Let

j_{1} = j_{2} = j_{3} = y, π (y) = a y, z (y) = y .

Moreover, we have

\int_{y_{0}}^{\infty} \frac{d s}{s} = \infty .

If we now set

θ_{1} (y) = θ_{2} (y) = k = 1,

we can easily find that the conditions of Theorem 1 are satisfied. So, Equation (52) is oscillatory. As a matter of fact, one such solution is

ξ (y) = sin (y) .

Example 2.

Consider the equation

ξ^{(4)} (y) + \frac{q_{0}}{y^{4}} ξ (y) = 0, y \geq 1, q_{0} > 0 .

(53)

Let

j_{1} = j_{2} = j_{3} = 1, n = 4, z (y) = y

and

π (y) = q_{0} / y^{4}

. Hence, it is easy to see that

δ (y) = y, σ (y) = \frac{1}{2} y^{2}

and

\begin{matrix} A (y) & = & \frac{1}{δ (y) σ (z_{r} (y))} (\int_{y_{3}}^{z (y)} \frac{σ (s) d s}{j_{1} (s)}) (\int_{y_{2}}^{z (y)} \frac{δ (s) d s}{j_{2} (s)}) \\ = & (\frac{2}{y^{3}}) (\frac{y^{3}}{6}) (\frac{y^{2}}{2}) = \frac{y^{2}}{6} . \end{matrix}

Now, if we set

θ_{1} (y) = θ_{2} (y) = y

and

k = 1

, then we see

\begin{matrix} \underset{y \to \infty}{lim sup} \frac{1}{y^{n}} \int_{y_{0}}^{y} {(y - s)}^{n} (k θ_{1} (y) \sum_{r = 1}^{m} π_{r} (y) A (y) - \frac{j_{3} (y) {(θ_{1}^{'} (y))}^{2}}{2 θ_{1} (y)}) d s \\ = & \underset{y \to \infty}{lim sup} \frac{1}{y^{2}} \int_{y_{0}}^{y} {(y - s)}^{2} (\frac{q_{0}}{6 s} - \frac{1}{2 s}) d s \\ = & \underset{y \to \infty}{lim sup} (\frac{q_{0}}{6} - \frac{1}{2}) \frac{1}{y^{2}} \int_{y_{0}}^{y} {(y - s)}^{2} \frac{1}{s} d s \end{matrix}

and

\begin{matrix} \underset{y \to \infty}{lim sup} \frac{1}{y^{n}} \int_{y_{0}}^{y} {(y - s)}^{n} (B (y) - \frac{j_{1} (y) {(θ_{2}^{'} (y))}^{2}}{4 θ_{2} (y)}) d s \\ = & \underset{y \to \infty}{lim sup} \frac{1}{y^{2}} \int_{y_{0}}^{y} {(y - s)}^{2} (\frac{π_{0}}{6 s} - \frac{1}{4 s}) d s . \end{matrix}

So, the conditions become

q_{0} > 3

(54)

and

q_{0} > 1.5 .

(55)

Thus, by Theorem 1, Equation (53) is oscillatory if

q_{0} > 3 .

4. Conclusions

It’s clear that the form of problem Equation (1) is more general than all the problems considered in [12,14]. In this paper, using the suitable Riccati-type transformation, we have offered some new sufficient conditions that ensure that any solution of Equation (1) oscillates under assumption

\int_{y_{0}}^{\infty} \frac{1}{j_{i} (s)} d s = \infty .

In addition, it would be useful to extend our results to fourth-order differential equations of the form

{({(j_{3} (y) {(j_{2} (y) {(j_{1} (y) ξ^{'} (y))}^{'})}^{'})}^{β})}^{'} + \sum_{r = 1}^{m} π_{r} (y) f (ξ (z_{r} (y))) = 0,

(56)

under condition

\int_{y_{0}}^{\infty} \frac{1}{j_{i}^{β} (s)} d s < \infty .

Author Contributions

Conceptualization, A.A., C.C., B.A. and O.B. These authors contributed equally to this work. All authors have read and agreed to the published version of the manuscript.

Funding

The authors received no direct funding for this work.

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. This research was funded by the Deanship of Scientific Research at Princess Nourah bint Abdulrahman University through the Fast-track Research Funding Program.

Conflicts of Interest

The authors declare no conflict of interest.

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AlGhamdi, A.; Cesarano, C.; Almarri, B.; Bazighifan, O. Symmetry and Its Importance in the Oscillation of Solutions of Differential Equations. Symmetry 2021, 13, 650. https://doi.org/10.3390/sym13040650

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AlGhamdi A, Cesarano C, Almarri B, Bazighifan O. Symmetry and Its Importance in the Oscillation of Solutions of Differential Equations. Symmetry. 2021; 13(4):650. https://doi.org/10.3390/sym13040650

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AlGhamdi, Ahmed, Clemente Cesarano, Barakah Almarri, and Omar Bazighifan. 2021. "Symmetry and Its Importance in the Oscillation of Solutions of Differential Equations" Symmetry 13, no. 4: 650. https://doi.org/10.3390/sym13040650

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Symmetry and Its Importance in the Oscillation of Solutions of Differential Equations

Abstract

1. Introduction

2. Some Lemmas

3. Oscillation Criteria

4. Conclusions

Author Contributions

Funding

Institutional Review Board Statement

Informed Consent Statement

Data Availability Statement

Acknowledgments

Conflicts of Interest

References

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