A Philos-Type Oscillation Criteria for Fourth-Order Neutral Differential Equations

Bazighifan, Omar; Cesarano, Clemente

doi:10.3390/sym12030379

Open AccessArticle

A Philos-Type Oscillation Criteria for Fourth-Order Neutral Differential Equations

by

Omar Bazighifan

^1,†

and

Clemente Cesarano

^2,*,†

¹

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

²

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

^*

Author to whom correspondence should be addressed.

^†

These authors contributed equally to this work.

Symmetry 2020, 12(3), 379; https://doi.org/10.3390/sym12030379

Submission received: 18 February 2020 / Revised: 24 February 2020 / Accepted: 25 February 2020 / Published: 3 March 2020

(This article belongs to the Special Issue Ordinary and Partial Differential Equations: Theory and Applications)

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Abstract

:

Some sufficient conditions are established for the oscillation of fourth order neutral differential equations of the form

{(r (t) {(z^{‴} (t))}^{α})}^{'} + q (t) x^{β} (σ (t)) = 0,

where

z (t) : = x (t) + p (t) x (τ (t))

. By using the technique of Riccati transformation and integral averaging method, we get conditions to ensure oscillation of solutions of this equation. Symmetry ideas are often invisible in these studies, but they help us decide the right way to study them, and to show us the correct direction for future developments. Moreover, the importance of the obtained conditions is illustrated via some examples.

Keywords:

fourth-order differential equations; neutral delay; oscillation; a philos-type

1. Introduction

Differential equations with a neutral argument have interesting applications in problems of real world life. In the networks containing lossless transmission lines, the neutral differential equations appear in the modeling of these phenomena as is the case in high-speed computers; see [1]. The theory of oscillation is an important branch of the qualitative theory of differential equations. In recent years, there has been a great deal of interest in studying oscillatory behavior of solutions to differential equations; see [2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28].

In the following, we show some previous results in in the literature which related to this paper: In 2019, Moaaz et al. [22] studied the oscillation of the even-order equation

{(r (t) {(z^{(n - 1)} (t))}^{α})}^{'} + \int_{a}^{b} q (t, s) f (x (σ (t, s))) d s = 0

and prove that it is oscillatory if

\int_{t_{0}}^{\infty} (k ρ (t) Q (t) - \frac{1}{4 λ} {(\frac{ρ^{'} (t)}{ρ (t)})}^{2} η (t)) d s = \infty,

also they used the technique of comparison with first order delay equations, Xing et al. [25] proved that the equation

{(r (t) {(z^{(n - 1)} (t))}^{α})}^{'} + + q (t) x^{α} (σ (t)) = 0,

is oscillatory if

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

and

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

where

0 \leq p (t) < p_{0} < \infty

and

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

.

Very recently, Chatzarakis et al. [10] established some oscillation criteria for neutral differential equation

{(r (t) {(z^{‴} (t))}^{α})}^{'} + \int_{a}^{b} q (t, s) f (x (σ (t, s))) d s = 0,

under the assumption

\int_{t_{0}}^{\infty} \frac{1}{r^{1 / α} (s)} d s = \infty,

(1)

by using the only Riccati transformations, prove that it is oscillatory if

\int_{t_{0}}^{\infty} (ϕ^{*} (t) - {(\frac{3}{α + 1})}^{α + 1} {(\frac{2}{λ_{0}})}^{α} t^{2 - 3 α} r (t)) d s = \infty,

where

ϕ^{*} (t) = k t^{3} Q (t) {(1 - p)}^{α} {(g (t, a) / t)}^{3 α} .

This paper is concerned with the oscillatory behavior of the fourth-order neutral delay differential equation

{(r (t) {(z^{‴} (t))}^{α})}^{'} + q (t) x^{β} (σ (t)) = 0,

(2)

where

t \geq t_{0}

and

z (t) : = x (t) + p (t) x (τ (t))

. Throughout this paper, we assume the following conditions to hold:

(S₁): $α$ and $β$ are quotient of odd positive integers;
(S₂): $r, p, q \in C [t_{0}, \infty),$ $r (t) > 0,$ $r^{'} (t) \geq 0,$ $q (t) > 0,$ $0 \leq p (t) < p_{0} < \infty,$ $τ, σ \in C [t_{0}, \infty),$ $τ (t) \leq t,$ ${lim}_{t \to \infty} τ (t) = {lim}_{t \to \infty} σ (t) = \infty;$

Moreover, we study (2) under the condition (1).

Definition 1.

The function x

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

is called a solution of (2), if

r (t) {(z^{(n - 1)} (t))}^{α} \in C^{1} [t_{x}, \infty),

and

x (t)

satisfies (2) on

[t_{x}, \infty)

.

Definition 2.

A solution of (2) is called oscillatory if it has arbitrarily large zeros on

[t_{x}, \infty),

and otherwise is called to be nonoscillatory.

Definition 3.

The equations (2) is said to be oscillatory if all its solutions are oscillatory.

Definition 4.

A neutral delay differential equation is a differential equation in which the highest-order derivative of the unknown function appears both with and without delay.

Definition 5.

Let

D = {(t, s) \in R^{2} : t \geq s \geq t_{0}} a n d D_{0} = {(t, s) \in R^{2} : t > s \geq t_{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): $H_{i} (t, s) = 0$ for $t \geq t_{0}, H_{i} (t, s) > 0, (t, s) \in D_{0};$
(ii): $H_{i} (t, s)$ has a continuous and nonpositive partial derivative $\partial H_{i} / \partial s$ on $D_{0}$ and there exist functions $ϑ, υ \in C^{1} ([t_{0}, \infty), (0, \infty))$ and $h_{i} \in C (D_{0}, R)$ such that

$\frac{\partial}{\partial s} H_{1} (t, s) + \frac{δ^{'} (s)}{δ (s)} H (t, s) = h_{1} (t, s) H_{1}^{α / (α + 1)} (t, s)$

(3)

and

$\frac{\partial}{\partial s} H_{2} (t, s) + \frac{ϑ^{'} (s)}{ϑ (s)} H_{2} (t, s) = h_{2} (t, s) \sqrt{H_{2} (t, s)} .$

(4)

In this work, by using the Riccati transformations and the integral averaging technique, we establish a new oscillation criterion for a class of fourth-order neutral delay differential equations (2). Our results improve and complement the results in [10]. Some examples are provided to illustrate the main results.

Here, we define the next notations:

\begin{matrix} Q_{1} (t) & = & δ (t) q (t) {(1 - p_{0})}^{β} A_{1}^{β - α} {(\frac{σ (t)}{t})}^{3 β}, \\ Φ (t) & = & {(1 - p_{0})}^{β / α} ϑ (t) A_{2}^{β / α - 1} (t) \int_{t}^{\infty} {(\frac{1}{r (u)} \int_{u}^{\infty} q (s) \frac{σ^{β} (s)}{s^{β}} d s)}^{1 / α} d u \end{matrix}

and

Θ (t) = α μ_{1} \frac{t^{2}}{2 r^{1 / α} (t) δ^{1 / α} (t)} .

2. Some Auxiliary Lemmas

We shall employ the following lemmas:

Lemma 1

([3], Lemma 2.2.3). Let

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

Assume that

x^{(n)} (t)

is of fixed sign and not identically zero on

[t_{0}, \infty)

and that there exists a

t_{1} \geq t_{0}

such that

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

for all

t \geq t_{1}

. If

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

then for every

μ \in (0, 1)

there exists

t_{μ} \geq t_{1}

such that

x (t) \geq \frac{μ}{(n - 1)!} t^{n - 1} |x^{(n - 1)} (t)| f o r t \geq t_{μ} .

Lemma 2

([18]). If the function x satisfies

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

i = 0, 1, \dots, n,

and

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

then

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

Lemma 3

([14]). Let

α

be a ratio of two odd numbers,

V > 0

and U are constants. Then

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

Lemma 4

([14], Lemma 1.2). Assume that

x

is an eventually positive solution of (2). Then, there exist two possible cases:

\begin{matrix} C a s e (N_{1}) : & z^{(j)} (t) > 0 & f o r & j = 0, 1, 2, 3 . \\ C a s e (N_{2}) : & z^{(j)} (t) > 0 & f o r & j = 0, 1, 3 a n d z^{″} (t) < 0 . \end{matrix}

for

t \geq t_{1},

where

t_{1} \geq t_{0}

is sufficiently large.

Lemma 5.

Assume that

x

is an eventually positive solution of (2). then

{(r (t) {(z^{‴} (t))}^{α})}^{'} \leq - G (t) {(z^{‴} (σ (t)))}^{β},

(5)

where

G (t) = q (t) {(1 - p_{0})}^{β} {(\frac{μ}{6} σ^{3} (t))}^{β} .

Proof.

Let x be an eventually positive solution of (2) on

[t_{0}, \infty)

. From definition of z, we get

\begin{matrix} x (t) & \geq & z (t) - p_{0} x (τ (t)) \\ \geq & z (t) - p_{0} z (τ (t)) \\ \geq & (1 - p_{0}) z (t), \end{matrix}

which with (2) gives

{(r (t) {(z^{‴} (t))}^{α})}^{'} + q (t) {(1 - p_{0})}^{β} z^{β} (σ (t)) \leq 0 .

(6)

Using Lemma 1, we see that

z (t) \geq \frac{μ}{6} t^{3} z^{‴} (t) .

(7)

Combining (6) and (7), we find

{(r (t) {(z^{‴} (t))}^{α})}^{'} + q (t) {(1 - p_{0})}^{β} {(\frac{μ}{6} σ^{3} (t))}^{β} {(z^{‴} (σ (t)))}^{β} \leq 0 .

Thus, (5) holds. This completes the proof. □

Lemma 6.

Assume that

x

is an eventually positive solution of (2) and

ξ^{'} (t) \leq \frac{δ^{'} (t)}{δ (t)} ξ (t) - Q_{1} (t) - α μ_{1} \frac{t^{2}}{2 r^{1 / α} (t) δ^{1 / α} (t)} ξ^{\frac{α + 1}{α}} (t), i f z s a t i s f i e s (N_{1})

(8)

and

φ^{'} (t) \leq - Φ (t) + \frac{ϑ^{'} (t)}{ϑ (t)} φ (t) - \frac{1}{ϑ (t)} φ^{2} (t), i f z s a t i s f i e s (N_{2}),

(9)

where

ξ (t) : = δ (t) \frac{r (t) {(z^{‴} (t))}^{α}}{z^{α} (t)}

(10)

and

φ (t) : = ϑ (t) \frac{z^{'} (t)}{z (t)}, t \geq t_{1} .

(11)

Proof.

Let x be an eventually positive solution of (2) on

[t_{0}, \infty)

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

(N_{1})

and

(N_{2})

.

Assume that Case

(N_{1})

holds. From the definition of

ξ (t)

, we see that

ξ (t) > 0

for

t \geq t_{1},

and using (6), we obtain

ξ^{'} (t) \leq \frac{δ^{'} (t)}{δ (t)} ξ (t) - δ (t) q (t) {(1 - p_{0})}^{β} \frac{z^{β} (σ (t))}{z^{α} (t)} - α δ (t) \frac{r (t) {(z^{‴} (t))}^{α}}{z^{α + 1} (t)} z^{'} (t) .

(12)

From Lemma 2, we have that

z (t) \geq \frac{t}{3} z^{'} (t)

, and hence,

\frac{z (σ (t))}{z (t)} \geq \frac{σ^{3} (t)}{t^{3}} .

(13)

It follows from Lemma 1 that

z^{'} (t) \geq \frac{μ_{1}}{2} t^{2} z^{‴} (t),

(14)

for all

μ_{1} \in (0, 1)

and every sufficiently large t. Thus, by (12)–(14), we get

\begin{matrix} ξ^{'} (t) & \leq & \frac{δ^{'} (t)}{δ (t)} ξ (t) - δ (t) q (t) {(1 - p_{0})}^{β} z^{β - α} (t) {(\frac{σ (t)}{t})}^{3 β} \\ - α μ_{1} \frac{t^{2}}{2 r^{1 / α} (t) δ^{1 / α} (t)} ξ^{\frac{α + 1}{α}} (t) . \end{matrix}

Since

z^{'} (t) > 0

, there exist a

t_{2} \geq t_{1}

and a constant

A_{1} > 0

such that

z (t) > A_{1} .

(15)

Thus, we obtain

\begin{matrix} ξ^{'} (t) & \leq & \frac{δ^{'} (t)}{δ (t)} ξ (t) - δ (t) q (t) {(1 - p_{0})}^{β} A^{β - α} {(\frac{σ (t)}{t})}^{3 β} \\ - α μ_{1} \frac{t^{2}}{2 r^{1 / α} (t) δ^{1 / α} (t)} ξ^{\frac{α + 1}{α}} (t), \end{matrix}

which yields

ξ^{'} (t) \leq \frac{δ^{'} (t)}{δ (t)} ξ (t) - Q_{1} (t) - α μ_{1} \frac{t^{2}}{2 r^{1 / α} (t) δ^{1 / α} (t)} ξ^{\frac{α + 1}{α}} (t) .

Thus, (8) holds. Assume that Case

(N_{2})

holds. Integrating (6) from t to u, we obtain

r (u) {(z^{‴} (u))}^{α} - r (t) {(z^{‴} (t))}^{α} \leq - \int_{t}^{u} q (s) {(1 - p_{0})}^{β} z^{β} (σ (s)) d s .

(16)

From Lemma 2, we get that

z (t) \geq t z^{'} (t)

, and hence,

z (σ (t)) \geq \frac{σ (t)}{t} z (t) .

(17)

For (16), letting

u \to \infty

and using (17), we get

r (t) {(z^{‴} (t))}^{α} \geq {(1 - p_{0})}^{β} z^{β} (t) \int_{t}^{\infty} q (s) \frac{σ^{β} (s)}{s^{β}} d s .

Integrating this inequality again from t to ∞, we get

z^{″} (t) \leq - {(1 - p_{0})}^{β / α} z^{β / α} (t) \int_{t}^{\infty} {(\frac{1}{r (u)} \int_{u}^{\infty} q (s) \frac{σ^{β} (s)}{s^{β}} d s)}^{1 / α} d u .

(18)

From the definition of

φ (t)

, we see that

φ (t) > 0

for

t \geq t_{1},

and using (15) and (18), we find

\begin{matrix} φ^{'} (t) & = & \frac{ϑ^{'} (t)}{ϑ (t)} φ (t) + ϑ (t) \frac{z^{″} (t)}{z (t)} - ϑ (t) {(\frac{z^{'} (t)}{z (t)})}^{2} \\ \leq & \frac{ϑ^{'} (t)}{ϑ (t)} φ (t) - \frac{1}{ϑ (t)} φ^{2} (t) \\ - {(1 - p_{0})}^{β / α} ϑ (t) z^{β / α - 1} (t) \int_{t}^{\infty} {(\frac{1}{r (u)} \int_{u}^{\infty} q (s) \frac{σ^{β} (s)}{s^{β}} d s)}^{1 / α} d u . \end{matrix}

Since

z^{'} (t) > 0

, there exist a

t_{2} \geq t_{1}

and a constant

A_{2} > 0

such that

z (t) > A_{2} .

(19)

Thus, we obtain

φ^{'} (t) \leq - Φ (t) + \frac{ϑ^{'} (t)}{ϑ (t)} φ (t) - \frac{1}{ϑ (t)} φ^{2} (t),

Thus, (9) holds. This completes the proof. □

3. Philos-Type Oscillation Result

In the section, we employ the integral averaging technique to establish a Philos-type oscillation criteria for (2)

Theorem 1.

Let (24) holds. If there exist positive functions

δ, ϑ \in C^{1} ([t_{0}, \infty), R)

such that

\underset{t \to \infty}{lim sup} \frac{1}{H (t, t_{1})} \int_{t_{1}}^{t} H (t, s) Q_{1} (s) - \frac{h_{1}^{α + 1} (t, s) H_{1}^{α} (t, s)}{{(α + 1)}^{α + 1}} \frac{2^{α} r (s) δ (s)}{{(μ_{1} s^{2})}^{α}} d s = \infty

(20)

for all

μ_{2} \in (0, 1),

and

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

(21)

then (2) is oscillatory.

Proof.

Let x be a non-oscillatory solution of (2) on

[t_{0}, \infty)

. Without loss of generality, we can assume that

x

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

(N_{1})

and

(N_{2})

. Assume that

(N_{1})

holds. From Lemma 6, we get that (8) holds. Multiplying (8) by

H (t, s)

and integrating the resulting inequality from

t_{1}

to t; we find that

\begin{matrix} \int_{t_{1}}^{t} H (t, s) Q_{1} (s) d s & \leq & ξ (t_{1}) H (t, t_{1}) + \int_{t_{1}}^{t} (\frac{\partial}{\partial s} H (t, s) + \frac{δ^{'} (s)}{δ (s)} H (t, s)) ξ (s) d s \\ - \int_{t_{1}}^{t} Θ (s) H (t, s) ξ^{\frac{α + 1}{α}} (s) d s . \end{matrix}

From (3), we get

\begin{matrix} \int_{t_{1}}^{t} H (t, s) Q_{1} (s) d s & \leq & ξ (t_{1}) H (t, t_{1}) + \int_{t_{1}}^{t} h_{1} (t, s) H_{1}^{α / (α + 1)} (t, s) ξ (s) d s \\ - \int_{t_{1}}^{t} Θ (s) H (t, s) ξ^{\frac{α + 1}{α}} (s) d s . \end{matrix}

(22)

Using Lemma 3 with

V = Θ (s) H (t, s), U = h_{1} (t, s) H_{1}^{α / (α + 1)} (t, s)

and

x = ξ (s)

, we get

\begin{matrix} h_{1} (t, s) H_{1}^{α / (α + 1)} (t, s) ξ (s) - Θ (s) H (t, s) ξ^{\frac{α + 1}{α}} (s) \\ \leq & \frac{h_{1}^{α + 1} (t, s) H_{1}^{α} (t, s)}{{(α + 1)}^{α + 1}} \frac{2^{α} r (t) δ (t)}{{(μ_{1} t^{2})}^{α}}, \end{matrix}

which, with (22) gives

\frac{1}{H (t, t_{1})} \int_{t_{1}}^{t} (H (t, s) Q_{1} (s) - \frac{h_{1}^{α + 1} (t, s) H_{1}^{α} (t, s)}{{(α + 1)}^{α + 1}} \frac{2^{α} r (s) δ (s)}{{(μ_{1} s^{2})}^{α}}) d s \leq ξ (t_{1}),

which contradicts (20). Assume that

(N_{2})

holds. From Lemma 6, we get that (9) holds. Multiplying (9) by

H_{2} (t, s)

and integrating the resulting inequality from

t_{1}

to t, we obtain

\begin{matrix} \int_{t_{1}}^{t} H_{2} (t, s) Φ (s) d s & \leq & φ (t_{1}) H_{2} (t, t_{1}) \\ + \int_{t_{1}}^{t} (\frac{\partial}{\partial s} H_{2} (t, s) + \frac{ϑ^{'} (s)}{ϑ (s)} H_{2} (t, s)) φ (s) d s \\ - \int_{t_{1}}^{t} \frac{1}{ϑ (s)} H_{2} (t, s) φ^{2} (s) d s . \end{matrix}

Thus,

\begin{matrix} \int_{t_{1}}^{t} H_{2} (t, s) Φ (s) d s & \leq & φ (t_{1}) H_{2} (t, t_{1}) + \int_{t_{1}}^{t} h_{2} (t, s) \sqrt{H_{2} (t, s)} φ (s) d s \\ - \int_{t_{1}}^{t} \frac{1}{ϑ (s)} H_{2} (t, s) φ^{2} (s) d s \\ \leq & φ (t_{1}) H_{2} (t, t_{1}) + \int_{t_{1}}^{t} \frac{ϑ (s) h_{2}^{2} (t, s)}{4} d s \end{matrix}

and so

\frac{1}{H_{2} (t, t_{1})} \int_{t_{1}}^{t} (H_{2} (t, s) Φ (s) - \frac{ϑ (s) h_{2}^{2} (t, s)}{4}) d s \leq φ (t_{1}),

which contradicts (21). This completes the proof. □

Corollary 1.

Assume that (24) holds. If there exist positive functions

δ, ϑ \in C^{1} ([t_{0}, \infty), R)

such that

\int_{t_{0}}^{\infty} (Q_{1} (s) - \frac{2^{α}}{{(α + 1)}^{α + 1}} \frac{r (s) {(δ^{'} (s))}^{α + 1}}{μ_{1}^{α} s^{2 α} δ^{α} (s)}) d s = \infty

(23)

and

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

(24)

for some

μ_{1} \in (0, 1)

and every

A_{1}, A_{2} > 0

, then (2) is oscillatory.

Example 1.

Consider the equation

{(t {(x + p_{0} x (γ t))}^{‴})}^{'} + \frac{q_{0}}{t^{3}} x (η t) = 0, t \geq 1,

(25)

where

p_{0} \in [0, 1), γ, η \in (0, 1)

and

q_{0} > 0

. We note that

α = β = 1,

r (t) = t,

p (t) = p_{0},

τ (t) = γ t,

σ (t) = η t

and

q (t) = q_{0} / t^{3}

. Hence, if we set

δ (s) : = t^{2}

and

ϑ (t) : = t

, then we have

Q_{1} (t) = \frac{q_{0} (1 - p_{0}) η^{3}}{t}, Φ (t) = \frac{q_{0} (1 - p_{0}) η}{4 t} .

Thus, (23) and (24) become

\begin{matrix} \int_{t_{0}}^{\infty} (Q_{1} (s) - \frac{2^{α}}{{(α + 1)}^{α + 1}} \frac{r (s) {(δ^{'} (s))}^{α + 1}}{μ_{1}^{α} s^{2 α} δ^{α} (s)}) d s \\ = & \int_{t_{0}}^{\infty} (\frac{q_{0} (1 - p_{0}) η^{3}}{s} - \frac{2}{μ_{1} s}) d s \end{matrix}

and

\begin{matrix} \int_{t_{0}}^{\infty} (Φ (s) - \frac{{(ϑ^{'} (s))}^{2}}{4 ϑ (s)}) d s \\ = & \int_{t_{0}}^{\infty} (\frac{q_{0} (1 - p_{0}) η}{4 s} - \frac{1}{4 s}) d s . \end{matrix}

So, the conditions become

q_{0} > \frac{2}{(1 - p_{0}) η^{3}}

(26)

and

q_{0} > \frac{1}{(1 - p_{0}) η} .

Thus, by using Corollary 1, Equation (27) is oscillatory if (26) holds.

Example 2.

Consider the equation

{(x + \frac{1}{2} x (\frac{1}{3} t))}^{(4)} + \frac{q_{0}}{t^{4}} x (\frac{1}{2} t) = 0, t \geq 1,

(27)

where

q_{0} > 0

. We note that

α = β = 1,

r (t) = 1,

p (t) = 1 / 2,

τ (t) = t / 3,

σ (t) = t / 2

and

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

. Hence, it is easy to see that

\int_{t_{0}}^{\infty} \frac{1}{r^{1 / α} (s)} d s = \infty .

Now, if we set

δ (s) : = t^{3}

and

ϑ (t) : = t^{2}

, then we have

\begin{matrix} \int_{t_{0}}^{\infty} (Q_{1} (s) - \frac{2^{α}}{{(α + 1)}^{α + 1}} \frac{r (s) {(δ^{'} (s))}^{α + 1}}{μ_{1}^{α} s^{2 α} δ^{α} (s)}) d s \\ = & \int_{t_{0}}^{\infty} (\frac{q_{0}}{16 s} - \frac{9}{2 μ_{1} s}) d s \end{matrix}

and

\begin{matrix} \int_{t_{0}}^{\infty} (Φ (s) - \frac{{(ϑ^{'} (s))}^{2}}{4 ϑ (s)}) d s \\ = & \int_{t_{0}}^{\infty} (\frac{q_{0}}{24} - 1) d s . \end{matrix}

So, the conditions become

q_{0} > 72

(28)

and

q_{0} > 24 .

(29)

Thus, by using Corollary 1, Equation (27) is oscillatory if

q_{0} > 72 .

4. Conclusions

In this paper, using technique of Riccati transformation, we will establish A Philos-type criteria for oscillation of the fourth-order neutral differential. Further, we can consider the case of

z (t) = x (t) + a (t) \sum_{i = 1}^{k} x^{α_{i}} (σ (t)) .

and we can try to get some oscillation criteria of (2) in future work.

Author Contributions

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

Funding

The authors received no direct funding for this work.

Acknowledgments

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

Conflicts of Interest

The authors declare no conflict of interest.

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Bazighifan, O.; Cesarano, C. A Philos-Type Oscillation Criteria for Fourth-Order Neutral Differential Equations. Symmetry 2020, 12, 379. https://doi.org/10.3390/sym12030379

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Bazighifan O, Cesarano C. A Philos-Type Oscillation Criteria for Fourth-Order Neutral Differential Equations. Symmetry. 2020; 12(3):379. https://doi.org/10.3390/sym12030379

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Bazighifan, O., & Cesarano, C. (2020). A Philos-Type Oscillation Criteria for Fourth-Order Neutral Differential Equations. Symmetry, 12(3), 379. https://doi.org/10.3390/sym12030379

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A Philos-Type Oscillation Criteria for Fourth-Order Neutral Differential Equations

Abstract

1. Introduction

2. Some Auxiliary Lemmas

3. Philos-Type Oscillation Result

4. Conclusions

Author Contributions

Funding

Acknowledgments

Conflicts of Interest

References

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