More Effective Criteria for Oscillation of Second-Order Differential Equations with Neutral Arguments

Moaaz, Osama; Anis, Mona; Baleanu, Dumitru; Muhib, Ali

doi:10.3390/math8060986

Open AccessArticle

More Effective Criteria for Oscillation of Second-Order Differential Equations with Neutral Arguments

¹

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

²

Department of Mathematics and Computer Science, Faculty of Arts and Sciences, Çankaya University Ankara, 06790 Etimesgut, Turkey

³

Instiute of Space Sciences, Magurele-Bucharest, 077125 Magurele, Romania

⁴

Department of Medical Research, China Medical University Hospital, China Medical University, Taichung 40402, Taiwan

⁵

Department of Mathematics, Faculty of Education (Al-Nadirah), Ibb University, Ibb, Yemen

^*

Author to whom correspondence should be addressed.

Mathematics 2020, 8(6), 986; https://doi.org/10.3390/math8060986

Submission received: 22 April 2020 / Revised: 2 June 2020 / Accepted: 3 June 2020 / Published: 16 June 2020

(This article belongs to the Special Issue Advances in Differential and Difference Equations with Applications 2023)

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Abstract

:

The motivation for this paper is to create new criteria for oscillation of solutions of second-order nonlinear neutral differential equations. In more than one respect, our results improve several related ones in the literature. As proof of the effectiveness of the new criteria, we offer more than one practical example.

Keywords:

second order differential equation; neutral delayed argument; oscillation

1. Introduction

In recent decades, an increasing interest in establishing sufficient criteria for oscillatory and non-oscillatory properties of different classes of differential equations has been observed; see, for instance, the monographs [1,2,3] and the references cited therein. Many authors were concerned with the oscillation and nonoscillation of delay differential equations of second-order [4,5,6,7,8,9,10,11,12,13,14,15,16,17] and higher-order [18,19,20,21,22,23]. The growing interest of delay differential equation is due to the many applications of these equations in different fields of science, see [24,25].

In this work, by using different techniques, we create new criteria for oscillation of 2nd-order neutral differential equation

{(r (ζ) {(z^{'} (ζ))}^{α})}^{'} + q (ζ) x^{β} (σ (ζ)) = 0,

(1)

where

ζ \geq ζ_{0}

and

z (ζ) : = x (ζ) + p (ζ) x (τ (ζ))

. Moreover, we assume that:

[N₁]: $α, β \in Q_{o d d}^{+},$ where $Q_{o d d}^{+} : = \{a / b : a, b \in Z^{+} are odd\}$ ;
[N₂]: $r \in C ([ζ_{0}, \infty)),$ $r (ζ) > 0$ and

$θ_{s} (ζ) : = \int_{s}^{ζ} r^{- 1 / α} (s) d s;$
[N₃]: $p, q \in C ([ζ_{0}, \infty)),$ $q (ζ) \geq 0,$ $0 \leq p (ζ) \leq p_{0} < \infty$ and $q (ζ)$ is not identically zero for large $ζ$ ;
[N₄]: $τ, σ \in C ([ζ_{0}, \infty)),$ $τ (ζ) \leq ζ,$ $σ (ζ) < ζ,$ and ${lim}_{ζ \to \infty} τ (ζ) = {lim}_{ζ \to \infty} σ (ζ) = \infty .$

If x

\in C^{1} [ζ_{x}, \infty), ζ_{x} \geq ζ_{0},

r (ζ) {(z^{'} (ζ))}^{α} \in C^{1} [ζ_{x}, \infty)

for all

ζ_{x} \geq ζ_{0}

, and x satisfies (1) on

[ζ_{x}, \infty)

, then x is called a solution of (1). Our attention will be solely to the solutions which satisfy

sup {|x (ζ)| : ζ \geq ζ} > 0,

for all

ζ \geq ζ_{x}

. If there exists a

ζ_{1} \geq ζ_{0}

such that either

x (ζ) > 0

or

x (ζ) < 0

for all

ζ \geq ζ_{1}

, then x is said to be a non-oscillatory solution; otherwise, it is said to be an oscillatory solution.

First, we will shed light on the studies of canonical equations that require

θ_{ζ_{0}} (\infty) = \infty

. By employing the Riccati transformation, Sun and Meng [16] studied the oscillation of delay Equation (1), with

p (ζ) = 0

and

α = β

. They proved that (1) is oscillatory if

\int_{ζ_{1}}^{\infty} (θ_{ζ_{1}}^{α} (σ (s)) q (s) - \frac{α^{α + 1} σ^{'} (s)}{{(α + 1)}^{α + 1} θ_{ζ_{1}} (σ (s)) r^{1 / α} (σ (s))}) d s = \infty .

Likewise, Xu and Meng [17] extended the results of [16] to the neutral case, and proved that if

\int_{ζ_{1}}^{\infty} (θ_{ζ_{1}}^{α} (σ (s)) G (s) - \frac{α^{α + 1} σ^{'} (s)}{{(α + 1)}^{α + 1} θ_{ζ_{1}} (σ (s)) r^{1 / α} (σ (s))}) d s = \infty, α = β,

then (1) is oscillatory, where

G (ζ) : = q (ζ) {(1 - p (σ (ζ)))}^{α}

.

By a different approach, by using comparison theorems that compare the second-order equation with first-order equations, Baculikova and Dzurina [5] proved that (1) is oscillatory if

α \geq β,

σ (ζ) \leq τ (ζ)

and

\underset{ζ \to \infty}{lim inf} \int_{τ^{- 1} (σ (ζ))}^{ζ} \hat{G} (s) {(\int_{ζ_{1}}^{σ (ζ)} r^{- 1 / α} (u) d u)}^{β} d s > {(1 + \frac{p_{0}^{β}}{τ_{0}})}^{β / α} \frac{1}{κ e},

(2)

where

\hat{G} (ζ) : = min \{q (ζ), q (τ (ζ))\}

(3)

and

κ : = \{\begin{matrix} 1 & if 0 < β \leq 1; \\ 2^{1 - β} & if β > 1 . \end{matrix}

(4)

Very recently, complementing the approach taken in [7], Grace et al. [11] improved the results in [5,13,17]. They established the following criteria for oscillation of (1) with

α = β

:

(a): By using comparison theory:

$\underset{ζ \to \infty}{lim inf} \int_{σ (ζ)}^{ζ} G (s) {(θ_{ζ_{1}}^{*} (σ (s)))}^{α} d s > \frac{1}{e},$

where

$θ_{ζ_{1}}^{*} (ζ) : = θ_{ζ_{1}} (ζ) + \frac{1}{α} \int_{ζ_{1}}^{ζ} θ_{ζ_{1}} (u) θ_{ζ_{1}}^{α} (u) d u;$
(b): By employing the Riccati transformation

$\underset{ζ \to \infty}{lim sup} \int_{ζ_{1}}^{\infty} (ϕ (s) exp (- \int_{σ (s)}^{s} \frac{d u}{r^{1 / α} (u) θ_{ζ_{1}}^{*} (u)}) - \frac{r (s) {(ϕ_{+}^{'} (s))}^{α + 1}}{{(α + 1)}^{α + 1} ϕ^{α} (s)}) d s = \infty,$

(5)

where $ϕ \in C ([ζ_{0}, \infty), (0, \infty))$ and $ϕ_{+}^{'} (ζ) : = max \{ϕ^{'} (ζ), 0\} .$

Moreover, Moaaz [14] extended the results of [11] to (1) when

α > β

and

α < β

.

On the other hand, there are many studies to improve the criteria for oscillation of solutions of non-canonical equations

θ_{ζ_{0}} (\infty) < \infty

, some of which we will refer to below.

Recently, Agarwal et al. [4] established conditions for oscillation of (1) which are an improvement for its predecessors. They proved that (1), with

β = α

, is oscillatory if

\underset{ζ \to \infty}{lim sup} \int_{ζ_{0}}^{ζ} (ρ (s) q (s) {(1 - p (σ (s)))}^{α} - \frac{{({(ρ^{'} (s))}_{+})}^{α + 1} r (τ (s))}{{(α + 1)}^{α + 1} ρ^{α} (s) {(τ^{'} (s))}^{α}}) d s = \infty

(6)

and

\underset{ζ \to \infty}{lim sup} \int_{ζ_{0}}^{ζ} (ψ (s) - \frac{δ (s) r (s) {({(φ (s))}_{+})}^{α + 1}}{{(α + 1)}^{α + 1}}) d s = \infty

(7)

hold, where

ψ (ζ) = δ (ζ) (q (ζ) {(1 - p (σ (ζ)) \frac{π (τ (σ (ζ)))}{π (σ (ζ))})}^{α} + \frac{1 - α}{r^{1 / α} (ζ) π^{α + 1} (ζ)}),

and

φ (ζ) = (δ^{'} (ζ) / δ (ζ)) + (1 + α) / (r^{1 / α} (ζ) π (ζ))

and

{(φ (ζ))}_{+} = max {φ (ζ), 0} .

Bohner et al. in [7], Theorem 2.4 simplified the criteria for oscillatory by setting one sufficient condition

\underset{ζ \to \infty}{lim inf} \int_{σ (ζ)}^{ζ} {(\frac{1}{r (ζ)} \int_{ζ_{1}}^{ζ} q (ζ) {(1 - p (σ (ζ)) \frac{π (τ (σ (ζ)))}{π (σ (ζ))})}^{α})}^{1 / α} d s > \frac{1}{e} .

The main purpose of this work is to improve conditions (2) and (5) by establishing a new criterion for oscillation of (1), which also takes into account the influence of delay argument

τ (ζ)

. Our approach is essentially based on presenting sharper criteria for oscillation solutions of (1) than criteria in [5,11]. Moreover, for non-canonical case, we improve and complete some results in [4,7]. As proof of the effectiveness of the new criteria, we offer more than one practical example.

2. Oscillation Theorems in Canonical Case

In this section, we establish new criteria for oscillation of solution of (1) in canonical case

θ_{ζ_{0}} (\infty) = \infty

. For convenience, we denote that:

Q (ζ) : = q (ζ) {(1 - p (σ (ζ)))}^{β},

\begin{matrix} {\tilde{θ}}_{ζ_{0}} (ζ) & : & = θ_{ζ_{0}} (ζ) + \frac{1}{α} \int_{ζ_{0}}^{ζ} θ_{ζ_{0}} (u) θ_{ζ_{0}}^{α} (σ (ζ)) η (σ (u)) Q (u) d u, \\ {\hat{θ}}_{ζ_{0}} (ζ) & : & = exp (- α \int_{σ (ζ)}^{ζ} \frac{1}{{\tilde{θ}}_{ζ_{0}} (s) r^{1 / α} (s)} d s), \\ ψ_{k} (ζ) & : & = \int_{ζ}^{\infty} {\hat{θ}}^{k} (u) η (σ (u)) Q (u) d u, k = 0, 1, \end{matrix}

and

η (ζ) : = \{\begin{matrix} c_{1}^{β - α} & if α \leq β; \\ c_{2} θ_{ζ_{2}}^{β - α} (ζ) & if α > β, \end{matrix}

where

c_{1}

and

c_{2}

are positive constants.

Lemma 1.

Assume that x is an eventually positive solution of (1). Then,

z (ζ) > 0, z^{'} (ζ) > 0 and (r (ζ) {(z^{'} (ζ))}^{α}) \leq 0,

(8)

for

ζ \geq ζ_{1}

, where

ζ_{1}

is sufficiently large. Moreover,

z^{β - α} (ζ) \geq η (ζ)

, eventually.

Proof.

First, we postulate that x is a positive solution of (1). From [5], Lemma 3, we have that (8) holds.

Next, let

α \leq β

. From the monotonicity of z, we get that

z (ζ) \geq z (ζ_{2}) : = c_{1} > 0

for

ζ \geq ζ_{2},

where

ζ_{2}

is sufficiently large.

In the case where

α > β

, since

r (ζ) {(z^{'} (ζ))}^{α}

is non-increasing, we have that

z (ζ) \leq z (ζ_{2}) + r^{1 / α} (ζ_{2}) z^{'} (ζ_{2}) θ_{ζ_{2}} (ζ),

for

ζ \geq ζ_{2}

. In view of the fact that

θ_{ζ_{2}} (\infty) = \infty

, there exists a

N > 0

and

ζ_{N} > ζ_{2}

such that

θ_{ζ_{2}} (ζ) > N

for all

ζ \geq ζ_{N}

. Thus,

z (ζ) \leq c_{2} θ_{ζ_{2}} (ζ)

where

c_{3} : = (z (ζ_{2}) / N + r^{1 / α} (ζ_{2}) z^{'} (ζ_{2}))

. Consequently,

z^{β - α} (ζ) \geq η (ζ)

. The proof is complete. □

Theorem 1.

Assume that

σ (ζ) \leq τ (ζ), τ^{'} (ζ) \geq τ_{0} > 0 and τ \circ σ = σ \circ τ .

If

\underset{ζ \to \infty}{lim inf} \int_{τ^{- 1} (σ (ζ))}^{ζ} \hat{G} (s) {\tilde{θ}}_{ζ_{1}}^{β} (σ (ζ)) d s > {(1 + \frac{p_{0}^{β}}{τ_{0}})}^{β / α} \frac{1}{κ e},

(9)

where

\hat{G} (s)

and κ defined as in (3) and (4), respectively, then all solutions of (1) are oscillatory.

Proof.

Suppose the contrary; that (1) has an eventually non-oscillatory solution. Without loss of generality, we assume that

x (ζ) > 0,

x (τ (ζ)) > 0

and

x (σ (ζ)) > 0

for

ζ \geq ζ_{1},

where

ζ_{1}

is sufficiently large. By Lemma 1, we have that (8) holds. Taking (8) into account, we obtain

x (ζ) \geq z (ζ) (1 - p (σ (ζ)))

, which with (1) gives

{(r (ζ) {(z^{'} (ζ))}^{α})}^{'} \leq - Q (ζ) z^{β} (σ (ζ)) .

(10)

Using the chain rule and simple computation, we see that

α {(r^{1 / α} z^{'})}^{α - 1} \frac{d}{d ζ} (z - θ_{ζ_{1}} r^{1 / α} z^{'}) = - α {(r^{1 / α} z^{'})}^{α - 1} θ_{ζ_{1}} {(r^{1 / α} z^{'})}^{'} = - θ_{ζ_{1}} {(r {(z^{'})}^{α})}^{'} .

(11)

From (10) and (11), we obtain

\begin{matrix} \frac{d}{d ζ} (z (ζ) - θ_{ζ_{1}} (ζ) r^{1 / α} (ζ) z^{'} (ζ)) & \geq & \frac{1}{α} {(r^{1 / α} (ζ) z^{'} (ζ))}^{1 - α} θ_{ζ_{1}} (ζ) Q (ζ) z^{β} (σ (ζ)) \\ \geq & \frac{1}{α} {(r^{1 / α} (ζ) z^{'} (ζ))}^{1 - α} θ_{ζ_{1}} (ζ) Q (ζ) η (σ (ζ)) z^{α} (σ (ζ)) . \end{matrix}

Integrating this inequality from

ζ_{1}

to

ζ

, we arrive at

z (ζ) \geq θ_{ζ_{1}} (ζ) r^{1 / α} (ζ) z^{'} (ζ) + \frac{1}{α} \int_{ζ_{1}}^{ζ} {(r^{1 / α} (u) z^{'} (u))}^{1 - α} θ_{ζ_{1}} (u) Q (u) η (σ (u)) z^{α} (σ (u)) d u .

(12)

From the monotonicity of

r^{1 / α} (ζ) z^{'} (ζ)

, we have

z (σ (ζ)) \geq θ_{ζ_{1}} (σ (ζ)) r^{1 / α} (σ (ζ)) z^{'} (σ (ζ)) \geq θ_{ζ_{1}} (σ (ζ)) r^{1 / α} (ζ) z^{'} (ζ) .

Thus, (12) becomes

z (ζ) \geq {\tilde{θ}}_{ζ_{1}} (ζ) r^{1 / α} (ζ) z^{'} (ζ) .

(13)

Proceeding as in the proof of Theorem 1 in [5] and using (13) instead of ((2.10) in [5]), we arrive at

{(ω (ζ) + \frac{p_{0}^{β}}{τ_{0}} ω (τ (ζ)))}^{'} + κ \hat{G} (ζ) {\tilde{θ}}_{ζ_{1}}^{β} (σ (ζ)) ω^{β / α} (σ (ζ)) \leq 0,

where

ω : = r^{1 / α} z^{'}

. Next, set

ψ (ζ) : = ω (ζ) + (p_{0}^{β} / τ_{0}) ω (τ (ζ)) > 0 .

Since

τ (ζ) \leq ζ

and

ω^{'} (t) \leq 0

, we obtain

\begin{matrix} ψ (ζ) & \leq & ω (τ (ζ)) + (p_{0}^{β} / τ_{0}) ω (τ (ζ)) \\ \leq & ω (τ (ζ)) (1 + \frac{p_{0}^{β}}{τ_{0}}) . \end{matrix}

Thus,

ψ

is a positive solution of

ψ^{'} (ζ) + κ {(\frac{τ_{0}}{τ_{0} + p_{0}^{β}})}^{β / α} \hat{G} (ζ) {\tilde{θ}}_{ζ_{1}}^{β} (σ (ζ)) ψ^{β / α} (τ^{- 1} (σ (ζ))) \leq 0 .

From Theorem 1 in [26], the equation

ψ^{'} (ζ) + κ {(\frac{τ_{0}}{τ_{0} + p_{0}^{β}})}^{β / α} \hat{G} (ζ) {\tilde{θ}}_{ζ_{1}}^{β} (σ (ζ)) ψ^{β / α} (τ^{- 1} (σ (ζ))) = 0,

(14)

also has a positive solution. It is well-known (see, e.g., [27], Theorem 2) that condition (9) implies oscillation of (14). This contradiction completes the proof. □

Theorem 2.

If

\underset{ζ \to \infty}{lim inf} \frac{α}{ψ_{1} (ζ)} \int_{ζ}^{\infty} r^{- 1 / α} (u) ψ_{1}^{(α + 1) / α} (u) d u > \frac{α}{{(α + 1)}^{(α + 1) / α}},

(15)

then all solutions of (1) are oscillatory.

Proof.

Proceeding as in the proof of Theorem 1, we arrive at (13). From (13), we see that

\frac{z (σ (ζ))}{z (ζ)} \geq exp (- \int_{σ (ζ)}^{ζ} \frac{1}{{\tilde{θ}}_{ζ_{1}} (s) r^{1 / α} (s)} d s) .

(16)

Define the function

w (ζ) : = \frac{r (ζ) {(z^{'} (ζ))}^{α}}{z^{α} (ζ)} .

(17)

Then

ω (ζ) > 0

for

ζ \geq ζ_{1}

. From (1) and (17), we get

w^{'} (ζ) \leq - Q (ζ) \frac{z^{α} (σ (ζ))}{z^{α} (ζ)} z^{β - α} (σ (ζ)) - \frac{α}{r^{1 / α} (ζ)} w^{(α + 1) / α} (ζ) .

Using Lemma 1 and (16), we obtain

w^{'} (ζ) \leq - \hat{θ} (ζ) η (σ (ζ)) Q (ζ) - \frac{α}{r^{1 / α} (ζ)} w^{(α + 1) / α} (ζ) < 0 .

(18)

By integrating (18) from

ζ

to

s,

we conclude that

\int_{ζ}^{s} \hat{θ} (u) η (σ (u)) Q (u) d u + α \int_{ζ}^{s} r^{- 1 / α} (u) w^{(α + 1) / α} (u) d u \leq w (ζ) - w (s) .

Since w is positive decreasing function, we see that

ψ_{1} (ζ) + α \int_{ζ}^{\infty} r^{- 1 / α} (u) w^{(α + 1) / α} (u) d u \leq w (ζ) .

Hence,

1 + \frac{α}{ψ_{1} (ζ)} \int_{ζ}^{\infty} r^{- 1 / α} (u) ψ^{(α + 1) / α} (u) {(\frac{w (u)}{ψ (u)})}^{(α + 1) / α} d u \leq \frac{w (ζ)}{ψ_{1} (ζ)} .

(19)

Set

δ : = inf_{ζ \geq ζ_{1}} \frac{w (ζ)}{ψ_{1} (ζ)} .

From (19),

δ \geq 1

. Taking (15) and (19) into account, we find

1 + α {(\frac{δ}{α + 1})}^{1 + 1 / α} \leq δ

or

{(\frac{δ}{α + 1})}^{α + 1} \leq {(\frac{δ - 1}{α})}^{α},

which is not possible with the permissible value

α > 0

and

δ \geq 1

. This contradiction completes the proof. □

In the following, we give an example to illustrate our main results.

Example 1.

Consider the differential equation

{({({(x (ζ) + p_{0} x (μ ζ))}^{'})}^{α})}^{'} + \frac{q_{0}}{ζ^{α + 1}} x^{α} (λ ζ) = 0,

(20)

where

q_{0} > 0

and

μ, λ \in (0, 1)

. We note that

θ_{ζ_{0}} (ζ) = ζ,

Q (ζ) = \frac{q_{0}}{ζ^{α + 1}} {(1 - p_{0})}^{α}, \hat{G} (ζ) : = \frac{q_{0}}{ζ^{α + 1}}, {\tilde{θ}}_{ζ_{0}} (ζ) = A ζ, \hat{θ} (ζ) = λ^{α / A}

and

ψ_{1} (ζ) = \frac{1}{α} λ^{α / A} q_{0} {(1 - p_{0})}^{α} \frac{1}{ζ^{α}},

where

A : = 1 + \frac{1}{α} q_{0} λ^{α} {(1 - p_{0})}^{α}

.

From Theorem 1, Equation (20) is oscillatory if

λ < μ

and

q_{0} {(A λ)}^{α} ln \frac{μ}{λ} > {(1 + \frac{p_{0}^{β}}{μ})}^{β / α} \frac{1}{κ e} .

(21)

Using Theorem 2, we have that if

{(\frac{1}{α} λ^{α / A} q_{0} {(1 - p_{0})}^{α})}^{1 / α} > \frac{α}{{(α + 1)}^{(α + 1) / α}}

or

q_{0} λ^{α / A} {(1 - p_{0})}^{α} > \frac{α^{α + 1}}{{(α + 1)}^{α + 1}},

(22)

then (20) is oscillatory.

As a particular case, the known criteria for oscillation of equation

{({({(x (ζ))}^{'})}^{1 / 3})}^{'} + \frac{q_{0}}{ζ^{4 / 3}} x^{1 / 3} (\frac{9}{10} ζ) = 0,

(23)

where

q_{0} > 0

, are:

Using Comparison Theory (As in [5])
C₁	Corollary 2 in [5]	q₀ < 3.61643
C₂	Condition (21)	q₀ < 1.92916
Using comparison theory (as in [11])
C₃	Corollary 2.1 in [11]	q₀ < 1.92916
By employing the Riccati transformation
C₄	Corollary 2.1 in [16]	q₀ < 0.16312
C₅	Theorem 6 in [11]	q₀ < 0.16243
C₆	Condition (22)	q₀ < 0.16131

Remark 1.

Note that, Theorem 1 improves Theorem 2 in [5]. The criterion of oscillation in Theorem 1 (as (21)) essentially takes into account the influence of delay argument

τ (ζ)

, which has been neglected in results of [11]. Moreover, Theorem 2 improves Theorem 6 in [11], and supports the most efficient condition for oscillation of Equation (20).

3. Oscillation Theorems in Non-Canonical Case

In the following, we derive new criteria for oscillation of solution of (1) in non-canonical case

θ_{ζ_{0}} (\infty) < \infty

. For convenience, we denote that:

θ_{ζ} (\infty) : = \bar{θ} (ζ)

and

Θ (ζ) : = q (ζ) {(1 - p (σ (ζ)) \frac{\bar{θ} (τ (σ (ζ)))}{\bar{θ} (σ (ζ))})}^{β} .

Lemma 2.

Let

Φ (ϱ) = L ϱ - M {(ϱ - N)}^{(α + 1) / α},

where

M > 0, L

and N are constants. Then, the maximum value of Φ on

R

is at

ϱ^{*} = N + {(α L / ((α + 1) M))}^{α}

and is given by

max_{ϱ \in R} Φ (ϱ) = Φ (ϱ^{*}) = L N + \frac{α^{α}}{{(α + 1)}^{(α + 1)}} \frac{L^{α + 1}}{M^{α}} .

Lemma 3.

Let x be an eventually positive solution of (1),

z^{'} (ζ) < 0

and

\int_{ζ_{0}}^{\infty} {(\frac{1}{r (ζ)} \int_{ζ_{1}}^{ζ} Θ (s) d s)}^{1 / α} d ζ = \infty

(24)

holds. If there exists a constant

δ \in [0, 1)

such that

\bar{θ} (ζ) {(η (ζ) \int_{ζ_{0}}^{ζ} Θ (s) d s)}^{1 / α} \geq δ,

(25)

then

\frac{d}{d ζ} (\frac{z (ζ)}{{\bar{θ}}^{δ} (ζ)}) \leq 0 .

(26)

Proof.

Suppose that x positive solution of (1) and

z^{'} (ζ) < 0

. We assume that

x (ζ) > 0,

x (τ (ζ)) > 0

and

x (σ (ζ)) > 0

for

ζ \geq ζ_{1},

where

ζ_{1}

is sufficiently large. Then, from (1), we obtain

z (ζ) > 0

and

{(r (ζ) {(z^{'} (ζ))}^{α})}^{'} = - q (ζ) x^{β} (σ (ζ)) < 0 .

(27)

Thus, we have

z (ζ) \geq - \int_{ζ}^{\infty} \frac{1}{r^{1 / α} (ϱ)} r^{1 / α} (ϱ) z^{'} (ϱ) d ϱ \geq - \bar{θ} (ζ) r^{1 / α} (ζ) z^{'} (ζ)

(28)

and so

\frac{d}{d ζ} (\frac{z (ζ)}{\bar{θ} (ζ)}) = \frac{\bar{θ} (ζ) z^{'} (ζ) + {(r (ζ))}^{- 1 / α} z (ζ)}{{\bar{θ}}^{2} (ζ)} \geq 0 .

Hence, we find

x (ζ) \geq (1 - p (ζ) \frac{\bar{θ} (τ (ζ))}{\bar{θ} (ζ)}) z (ζ),

which with (27) gives

{(r (ζ) {(z^{'} (ζ))}^{α})}^{'} \leq - Θ (ζ) z^{β} (σ (ζ)) .

(29)

Next, since z is a positive decreasing function, we have that

{lim}_{ζ \to \infty} z (ζ) = ϵ \geq 0

. Let

ϵ > 0

. Then, from (29), there exists a

ζ_{1} \geq ζ_{0}

such that

{(r (ζ) {(z^{'} (ζ))}^{α})}^{'} \leq - Θ (ζ) z^{β} (σ (ζ)) \leq - ϵ^{β} Θ (ζ) .

Integrating this inequality from

ζ_{1}

to

ζ

, we have

- z^{'} (ζ) \geq ϵ^{β / α} {(\frac{1}{r (ζ)} \int_{ζ_{1}}^{ζ} Θ (s) d s)}^{1 / α} .

(30)

Integrating (30) from

ζ_{1}

to

ζ

, we get

z (ζ) \leq z (ζ_{1}) - ϵ^{β / α} \int_{ζ_{1}}^{ζ} {(\frac{1}{r (ϱ)} \int_{ζ_{1}}^{ϱ} Θ (s) d s)}^{1 / α} d ϱ .

Taking

{lim}_{ζ \to \infty}

of this inequality and using (24), we arrive at a contradiction with positivity of z. Therefore, we get that

ϵ = 0

that is

lim_{ζ \to \infty} x (ζ) = lim_{ζ \to \infty} z (ζ) = 0 .

(31)

Integrating (29) from

ζ_{1}

to

ζ

, we get

\begin{matrix} r (ζ) {(z^{'} (ζ))}^{α} & \leq & r (ζ_{1}) {(z^{'} (ζ_{1}))}^{α} - \int_{ζ_{1}}^{ζ} Θ (s) z^{β} (σ (s)) d s \\ \leq & r (ζ_{1}) {(z^{'} (ζ_{1}))}^{α} - z^{β} (σ (ζ)) \int_{ζ_{1}}^{ζ} Θ (s) d s . \end{matrix}

(32)

In view of (31), we see that

r (ζ_{1}) {(z^{'} (ζ_{1}))}^{α} + z^{β} (σ (ζ)) \int_{ζ_{0}}^{ζ_{1}} Θ (s) d s > 0,

(33)

for

ζ \geq ζ_{2},

where

ζ_{2}

large enough. Combining (32) and (33) and using the fact that

z^{β - α} (ζ) \geq η (ζ)

, we find

r (ζ) {(z^{'} (ζ))}^{α} \leq - z^{β} (σ (ζ)) \int_{ζ_{0}}^{ζ} Θ (s) d s \leq - η (ζ) z^{α} (ζ) \int_{ζ_{0}}^{ζ} Θ (s) d s,

(34)

which with (25) gives

\begin{matrix} z^{'} (ζ) & \leq & - r {(ζ)}^{- 1 / α} z (ζ) {(η (ζ) \int_{ζ_{0}}^{ζ} Θ (s) d s)}^{1 / α} \\ \leq & - \frac{δ}{\bar{θ} (ζ)} r {(ζ)}^{- 1 / α} z (ζ) . \end{matrix}

Thus, we have

\frac{d}{d ζ} (\frac{z (ζ)}{{\bar{θ}}^{δ} (ζ)}) = \frac{{\bar{θ}}^{δ - 1} (ζ) (\bar{θ} (ζ) z^{'} (ζ) + δ {(μ (ζ) r (ζ))}^{- 1 / α} z (ζ))}{{\bar{θ}}^{2 δ} (ζ)} \leq 0 .

This completes the proof. □

Theorem 3.

Assume that (24) holds,

\bar{θ} (τ (ζ)) \geq \bar{θ} (ζ)

and there exists a

δ \in [0, 1)

such that (25) holds. If there exist a function

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

and a

ζ_{1} \in [ζ_{0}, \infty)

such that

\underset{ζ \to \infty}{lim sup} \{\frac{{\bar{θ}}^{α} (ζ)}{ρ (ζ)} \int_{ζ_{1}}^{ζ} (ρ (ϱ) Θ (ϱ) η (ϱ) {(\frac{\bar{θ} (σ (ϱ))}{\bar{θ} (ϱ)})}^{δ β} - \frac{r (ϱ) {(ρ^{'} (ϱ))}^{α + 1}}{{(α + 1)}^{α + 1} ρ^{α} (ϱ)}) d ϱ\} > 1,

(35)

then all solutions of (1) are oscillatory.

Proof.

Assuming that the required result is not fulfilled, we suppose, without loss of generality, that x is a positive solution of (1) on

[ζ_{0}, \infty)

. Then, there exists

ζ_{1} \geq ζ_{0}

such that

x (τ (ζ)) > 0

and

x (σ (ζ)) > 0

for all

ζ \geq ζ_{1} .

Obviously, for all

ζ \geq ζ_{1},

z (ζ) \geq x (ζ) > 0

and

{(r {(z^{'})}^{α})}^{'} \leq 0

. Therefore,

z^{'} (ζ)

is either eventually negative or eventually positive.

Assume first that

z^{'} (ζ) < 0 .

From Lemma 3, we get that (28) and (29) hold. We define the function

w : = ρ (\frac{r {(z^{'})}^{α}}{z^{α}} + \frac{1}{{\bar{θ}}^{α}}) .

(36)

Using (28), we see that

w (ζ) \geq 0

for all

ζ \geq ζ_{2} \geq ζ_{1}

. Differentiating (36), we get

w^{'} = \frac{ρ^{'}}{ρ} w + ρ \frac{{(r {(z^{'})}^{α})}^{'}}{z^{α}} - α ρ \frac{r {(z^{'})}^{α + 1}}{z^{α + 1}} + α ρ \frac{1}{r^{1 / α} {\bar{θ}}^{α + 1}} .

From Lemma 1, (29) and (36), we obtain

w^{'} \leq - \frac{α}{{(ρ r)}^{1 / α}} {(w - \frac{ρ}{{\bar{θ}}^{α}})}^{1 + 1 / α} - ρ Θ η \frac{z^{β} (σ)}{z^{β}} + α ρ \frac{1}{r^{1 / α} {\bar{θ}}^{α + 1}} + \frac{ρ^{'}}{ρ} w .

(37)

Using Lemma 2 with

L : = ρ^{'} / ρ,

M : = α / {(ρ r)}^{1 / α},

N = ρ / {\bar{θ}}^{α}

and

ϱ : = w

, we get

\frac{ρ^{'}}{ρ} w - \frac{α}{{(ρ r)}^{1 / α}} {(w - \frac{ρ}{{\bar{θ}}^{α}})}^{1 + 1 / α} \leq \frac{ρ^{'}}{{\bar{θ}}^{α}} + \frac{r}{{(α + 1)}^{α + 1}} \frac{{(ρ^{'})}^{α + 1}}{ρ^{α}},

which with (37) gives

w^{'} \leq \frac{ρ^{'}}{{\bar{θ}}^{α}} + \frac{r}{{(α + 1)}^{α + 1}} \frac{{(ρ^{'})}^{α + 1}}{ρ^{α}} - ρ Θ η \frac{z^{β} (σ)}{z^{β}} + α ρ \frac{1}{r^{1 / α} {\bar{θ}}^{α + 1}} .

(38)

From Lemma 3 we arrive at (26). From (26), we conclude that

\frac{z (σ (ζ))}{z (ζ)} \geq \frac{{\bar{θ}}^{δ} (σ (ζ))}{{\bar{θ}}^{δ} (ζ)} .

(39)

Thus, (38) becomes

w^{'} \leq - ρ Θ η {(\frac{\bar{θ} (σ (ζ))}{\bar{θ} (ζ)})}^{δ β} + \frac{r}{{(α + 1)}^{α + 1}} \frac{{(ρ^{'})}^{α + 1}}{ρ^{α}} + {(\frac{ρ}{{\bar{θ}}^{α}})}^{'} .

Integrating this inequality from

ζ_{2}

to

ζ

, we have

\begin{matrix} \int_{ζ_{2}}^{ζ} (ρ (ϱ) Θ (ϱ) η (ϱ) {(\frac{\bar{θ} (σ (ϱ))}{\bar{θ} (ϱ)})}^{δ β} - \frac{r (ϱ) {(ρ^{'} (ϱ))}^{α + 1}}{{(α + 1)}^{α + 1} ρ^{α} (ϱ)}) d ϱ \\ \leq {(\frac{ρ (ζ)}{{\bar{θ}}^{α} (ζ)} - w (ζ))|}_{ζ_{2}}^{ζ} \\ \leq {- (ρ (ζ) \frac{r (ζ) {(z^{'} (ζ))}^{α}}{z^{α} (ζ)})|}_{ζ_{2}}^{ζ} . \end{matrix}

(40)

From (28), we have

- \frac{r {(ζ)}^{1 / α} z^{'} (ζ)}{z (ζ)} \leq \frac{1}{\bar{θ} (ζ)},

which in view of (40) implies

\frac{{\bar{θ}}^{α} (ζ)}{ρ (ζ)} \int_{ζ_{2}}^{ζ} (ρ (ϱ) Θ (ϱ) η (ϱ) {(\frac{\bar{θ} (σ (ϱ))}{\bar{θ} (ϱ)})}^{δ β} - \frac{r (ϱ) {(ρ^{'} (ϱ))}^{α + 1}}{{(α + 1)}^{α + 1} ρ^{α} (ϱ)}) d ϱ \leq 1 .

Taking the lim sup on both sides of this inequality, we arrive at a contradiction with (35).

Now assume that

z^{'} (ζ) > 0 .

Since

z^{'} > 0

and

\bar{θ} (τ (ζ)) \geq \bar{θ} (ζ) .

Then

x (ζ) \geq (1 - p (ζ)) z (ζ) \geq (1 - p (ζ) \frac{\bar{θ} (τ (ζ))}{\bar{θ} (ζ)}) z (ζ) .

(41)

From (1) and (41), we have

\begin{matrix} {(r (ζ) {(z^{'} (ζ))}^{α})}^{'} & \leq & - q (ζ) {(1 - p (σ (ζ)) \frac{\bar{θ} (τ (σ (ζ)))}{\bar{θ} (σ (ζ))})}^{β} z^{β} (σ (ζ)) \\ \leq & - Θ (ζ) z^{β} (σ (ζ)) . \end{matrix}

Integrating the above inequality from

ζ_{2}

to

ζ

, we have

\begin{matrix} r (ζ) {(z^{'} (ζ))}^{α} & \leq & r (ζ_{2}) {(z^{'} (ζ_{2}))}^{α} - \int_{ζ_{2}}^{ζ} Θ (s) z^{β} (σ (s)) d s \\ \leq & r (ζ_{2}) {(z^{'} (ζ_{2}))}^{α} - z^{β} (σ (ζ_{2})) \int_{ζ_{2}}^{ζ} Θ (s) d s . \end{matrix}

(42)

Now, from (24) and

θ_{ζ_{0}} (\infty) < \infty

, we get that

\int_{ζ_{1}}^{ζ} Θ (s) d s

must be unbounded, that is

\int_{ζ_{1}}^{\infty} Θ (s) d s = \infty .

(43)

From (42) and (43), we get contradictions to

z^{'} > 0

as

ζ \to \infty .

The proof is complete. □

Corollary 1.

Assume that (24) holds,

\bar{θ} (τ (ζ)) \geq \bar{θ} (ζ)

and there exists a

δ \in [0, 1)

such that (25) holds. If there exists a

ζ_{1} \in [ζ_{0}, \infty)

such that

\underset{ζ \to \infty}{lim sup} \int_{ζ_{1}}^{ζ} ({\bar{θ}}^{α} (ϱ) Θ (ϱ) η (ϱ) {(\frac{\bar{θ} (σ (ϱ))}{\bar{θ} (ϱ)})}^{δ β} - {(\frac{α}{α + 1})}^{α + 1} \frac{1}{r^{1 / α} (ϱ) \bar{θ} (ϱ)}) d ϱ > 1,

(44)

then all solutions of (1) are oscillatory.

Example 2.

Consider the second-order differential equation

{(ζ^{α + 1} {({(x (ζ) + p_{0} x (κ ζ))}^{'})}^{α})}^{'} + q_{0} x^{α} (λ ζ) = 0, ζ \geq 1,

(45)

where

q_{0} > 0

and

κ, λ \in (0, 1]

. Note that,

r (ζ) = ζ^{α + 1}, p (ζ) = p_{0},

τ (ζ) = κ ζ, q (ζ) = q_{0}, σ (ζ) = λ ζ

and

β = α

. It is easy to conclude that

η (ζ) = 1, \bar{θ} (ζ) = α / ζ^{1 / α}

and

Θ (ζ) = q_{0} {(1 - 2^{1 / α} p_{0})}^{α}

. We note that the conditions (24) and (25) hold. Furthermore, condition (44) becomes

\underset{ζ \to \infty}{lim sup} \int_{ζ_{0}}^{ζ} (\frac{α^{α}}{s} q_{0} {(1 - 2^{1 / α} p_{0})}^{α} \frac{1}{λ^{δ}} - {(\frac{α}{α + 1})}^{α + 1} \frac{1}{α s}) d s > 1 .

Using Corollary 1, we get that every solution of Equation (45) is oscillatory if

q_{0} {(1 - 2^{1 / α} p_{0})}^{α} \frac{1}{λ^{δ}} > \frac{1}{{(α + 1)}^{α + 1}} .

(46)

From Theorem 2.2 in [4], (45) is oscillatory if

α \geq 1

and

q_{0} {(1 - 2^{1 / α} p_{0})}^{α} > \frac{1 - (1 - α) {(α + 1)}^{α + 1}}{α^{α + 1} {(α + 1)}^{α + 1}} .

(47)

By using Theorem 2.4 in [7], (45) is oscillatory if

q_{0}^{1 / α} (1 - 2^{1 / α} p_{0}) ln \frac{1}{λ} > \frac{1}{e} .

(48)

Consider the special case in which

α = 1,

κ = λ = 1 / 2,

p_{0} = 1 / 4

and

q_{0} = \sqrt{2} / 3

, that is,

{(ζ^{2} {({(x (ζ) + \frac{1}{4} x (\frac{1}{2} ζ))}^{'})}^{α})}^{'} + \frac{\sqrt{2}}{3} x (\frac{1}{2} ζ) = 0 .

We note that the criteria arrive at

\sqrt{2} / 3 > 0.4307,

\sqrt{2} / 3 > 0.5

and

\sqrt{2} / 3 > 1.0615

. Hence, it is obvious that (47) and (48) fail to apply.

4. Conclusions

During this work, we highlighted the oscillatory properties of solutions of differential Equation (1). By using many techniques, we have created new criteria that are more effective than the relevant criteria in the literature. Moreover, we discussed oscillatory behavior in both canonical and non-canonical cases. Through the examples, it turns out that our results improve and complete some of the results in [4,5,7,11,16]. Finally, we can try to extend our results to differential equations with a damping term, in the future.

Author Contributions

Formal analysis, O.M., M.A., D.B., A.M.; investigation, O.M., D.B.; writing—original draft preparation, O.M., D.B.; writing—review and editing, M.A., A.M. All authors have read and agreed to the published version of the manuscript.

Funding

This research received no external funding.

Conflicts of Interest

The authors declare no conflict of interest.

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Moaaz, O.; Anis, M.; Baleanu, D.; Muhib, A. More Effective Criteria for Oscillation of Second-Order Differential Equations with Neutral Arguments. Mathematics 2020, 8, 986. https://doi.org/10.3390/math8060986

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Moaaz O, Anis M, Baleanu D, Muhib A. More Effective Criteria for Oscillation of Second-Order Differential Equations with Neutral Arguments. Mathematics. 2020; 8(6):986. https://doi.org/10.3390/math8060986

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Moaaz, Osama, Mona Anis, Dumitru Baleanu, and Ali Muhib. 2020. "More Effective Criteria for Oscillation of Second-Order Differential Equations with Neutral Arguments" Mathematics 8, no. 6: 986. https://doi.org/10.3390/math8060986

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More Effective Criteria for Oscillation of Second-Order Differential Equations with Neutral Arguments

Abstract

1. Introduction

2. Oscillation Theorems in Canonical Case

3. Oscillation Theorems in Non-Canonical Case

4. Conclusions

Author Contributions

Funding

Conflicts of Interest

References

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