Second-Order Non-Canonical Neutral Differential Equations with Mixed Type: Oscillatory Behavior

Moaaz, Osama; Nabih, Amany; Alotaibi, Hammad; Hamed, Y. S.

doi:10.3390/sym13020318

Open AccessArticle

Second-Order Non-Canonical Neutral Differential Equations with Mixed Type: Oscillatory Behavior

¹

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

²

Department of Mathematics and Statistics, College of Science, Taif University, P. O. Box 11099, Taif 21944, Saudi Arabia

^*

Author to whom correspondence should be addressed.

^†

These authors contributed equally to this work.

Symmetry 2021, 13(2), 318; https://0-doi-org.brum.beds.ac.uk/10.3390/sym13020318

Submission received: 12 January 2021 / Revised: 6 February 2021 / Accepted: 10 February 2021 / Published: 14 February 2021

(This article belongs to the Special Issue Symmetry in Modeling and Analysis of Dynamic Systems)

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Abstract

:

In this paper, we establish new sufficient conditions for the oscillation of solutions of a class of second-order delay differential equations with a mixed neutral term, which are under the non-canonical condition. The results obtained complement and simplify some known results in the relevant literature. Example illustrating the results is included.

Keywords:

non-canonical differential equations; second-order; neutral delay; mixed type; oscillation criteria

1. Introduction

This paper discusses the oscillatory behavior of solutions of second-order functional differential equation with a mixed neutral term of the form

{(r (l) {[{(y (l) + p_{1} (l) y (ρ_{1} (l)) + p_{2} (l) y (ρ_{2} (l)))}^{'}]}^{γ})}^{'} + q (l) y^{γ} (σ (l)) = 0,

(1)

where

l \geq l_{0}

. Throughout this paper, we assume the following:

(C1): $γ \in Q_{o d d}^{+} : = \{a / b : a, b \in Z^{+} are odd\}$ and $r \in C ([l_{0}, \infty), (0, \infty));$
(C2): $ρ_{1}, ρ_{2}, σ \in C ([l_{0}, \infty), R)$ , $ρ_{1} (l) \leq l \leq ρ_{2} (l),$ $σ (l) \leq l$ and $ρ_{1}, ρ_{2}, σ \to \infty$ as $l \to \infty;$
(C3): $p_{1}, p_{2}, q \in C ([l_{0}, \infty), [0, \infty))$ and $q (l)$ is not identically zero for large l.

Let y be a real-valued function defined for all l in a real interval

[l_{y}, \infty), l_{y} \geq l_{0},

and having a second derivative for all

l \in [l_{y}, \infty)

. The function y is called a

solution

of the differential Equation (1) on

[l_{y}, \infty)

if

y

satisfies (1) on

[l_{y}, \infty) .

A nontrivial solution y of any differential equation is said to be

oscillatory

if it has arbitrary large zeros; otherwise, it is said to be

nonoscillatory

. We will consider only those solutions of (1) which exist on some half-line

[l_{b}, \infty)

for

l_{b} \geq l_{0}

and satisfy the condition

sup \{|y (l)| : l_{c} \leq l < \infty\} > 0

for any

l_{c} \geq l_{b} .

A delay differential equation of neutral type is an equation in which the highest order derivative of the unknown function appears both with and without delay. During the last decades, there is a great interest in studying the oscillation of solutions of neutral differential equations. This is due to the fact that such equations arise from a variety of applications including population dynamics, automatic control, mixing liquids, and vibrating masses attached to an elastic bar, biology in explaining self-balancing of the human body, and in robotics in constructing biped robots, it is easy to notice the emergence of models of the neutral delay differential equations, see [1,2].

In the following, we review some of the related works that dealt with the oscillation of the neutral differential equations of mixed-type.

Grammatikopouls et al. [3] established oscillation criteria for the equation

{(r (l) ψ^{'} (l))}^{'} + q (l) y (σ (l)) = 0,

(2)

where

z (l) = y (l) + p_{1} (l) y (l - σ_{1}) + p_{2} (l) y (l + σ_{2}),

r (l) = 1

,

p_{2} (l) = 0

,

0 \leq p_{1} \leq 1,

and

q (l) \geq 0

. Ruan [4] obtained some oscillation criteria for the Equation (2) by employing Riccati technique and averaging function method, when

p_{2} (l) = 0

and

σ (l) = l - σ

. Arul and Shobha [5] studied the oscillatory behavior of solution of (2), when

0 \leq p_{1} (l) \leq p_{1} < \infty

and

0 \leq p_{2} (l) \leq p_{2} < \infty

.

Dzurina et al. [6] presented some sufficient conditions for the oscillation of the second-order equation

{(\frac{1}{r (l)} y^{'} (l))}^{'} + p (l) y (τ (l)) + q (l) y (σ (l)) = 0 .

Li [7] and Li et al. [8] studied the oscillation of solutions of the second-order equation with constant mixed arguments:

{(r (l) z^{'} (l))}^{'} + q_{1} (l) y (l - σ_{3}) + q_{2} (l) y (l + σ_{4}) = 0 .

(3)

Arul and Shobha [5] established some sufficient conditions for the oscillation of all solutions of Equation (3) in the canonical case, that is,

\int_{l_{0}}^{\infty} r^{- 1} (ϑ) d ϑ = \infty,

Thandapani et al. [9] studied the oscillation criteria for the differential equation of the form

{(z^{α} (l))}^{″} + q (l) y^{β} (l - τ_{1}) + p (l) y^{γ} (l + τ_{1}) = 0 .

Grace et al. [10] studied the oscillatory behavior of solutions of the equation

{(r (l) {({(y (l) + p_{1} (l) y^{β_{1}} (σ_{1} (l)) + p_{2} (l) y^{β_{2}} (σ_{2} (l)))}^{'})}^{γ})}^{'} + q (l) y^{γ} (τ (l)) = 0,

and considered the two cases

\int_{l_{0}}^{\infty} r^{- 1 / γ} (ϑ) d ϑ = \infty,

(4)

and

\int_{l_{0}}^{\infty} r^{- 1 / γ} (ϑ) d ϑ < \infty .

(5)

In [11], Tunc et al. studied the oscillatory behavior of the differential Equation (1) under the condition (4). Moreover, they considered the two following cases:

p_{1} (l) \geq 0

,

p_{2} (l) \geq 1

, and

p_{2} (l) \neq 1

eventually;

p_{2} (l) \geq 0

,

p_{1} (l) \geq 1

, and

p_{2} (l) \neq 1

eventually.

For the third-order equations, Han et al. [12] studied the oscillation and asymptotic properties of the third-order equation

{(a (l) z^{″} (l))}^{'} + q_{1} (l) y (l - τ_{3}) + q_{2} (l) y (l + τ_{4}) = 0,

and established two theorems which guarantee that the above equation oscillates or tends to zero. Moaaz et al. [13] discussed the oscillation and asymptotic behavior of solutions of the third-order equation

{(r (l) {(x^{″} (l))}^{α})}^{'} + q_{1} (l) f_{1} (y (σ_{1} (l))) + q_{2} (l) f_{2} (y (σ_{2} (l))) = 0,

where

x (l) = y (l) + p_{1} (l) y (τ_{1} (l)) + p_{2} (l) y (τ_{2} (l))

. For further results, techniques, and approaches in studying oscillation of the delay differential equations, see in [14,15,16,17,18,19,20,21,22,23,24].

In this paper, we study the oscillatory behavior of solutions of the second-order differential equation with a mixed neutral term (1) under condition (5). We follow a new approach based on deducing a new relationship between the solution and the corresponding function. Using this new relationship, we first obtain one condition that ensures oscillation of (1). Moreover, by introducing a generalized Riccati substitution, we get a new criterion for oscillation of (1). Often these types of equations (such as (1), (2), and (3)) are studied under condition (4). On the other hand, the works that studied these equations under the condition (5) obtained two conditions to ensure the oscillation. Therefore, our results are an extension and simplification as well as improvement of previous results in [3,4,5,8,11].

2. Main Results

We adopt the following notation for a compact presentation of our results:

ψ (l) : = y (l) + p_{1} (l) y (ρ_{1} (l)) + p_{2} (l) y (ρ_{2} (l)),

κ (u, v) : = \int_{u}^{v} r^{- 1 / γ} (δ) d δ,

B_{1} (l) : = 1 - p_{1} (l) \frac{κ (ρ_{1} (l), \infty)}{κ (l, \infty)} - p_{2} (l)

and

B_{2} (l) : = 1 - p_{1} (l) - p_{2} (l) \frac{κ (l_{1}, ρ_{2} (l))}{κ (l_{1}, l)} .

Lemma 1.

Assume that

Θ (ϑ) : = A ϑ - B {(ϑ - C)}^{(γ + 1) / γ}

, where A, B and C are real constants;

B > 0

; and

γ \in Q_{o d d}^{+}

. Then,

Θ (ϑ^{*}) \leq max_{u \in R} Θ (ϑ) = A C + \frac{γ^{γ}}{{(γ + 1)}^{γ + 1}} A^{γ + 1} B^{- γ} .

Lemma 2.

Assume that y is a positive solution of (1) on

[l_{0}, \infty)

. If ψ is a decreasing positive function for

l \geq l_{1}

large enough, then

{(\frac{ψ (l)}{κ (l, \infty)})}^{'} \geq 0, f o r l \geq l_{1} .

(6)

While if ψ is a increasing positive function for

l \geq l_{1}

, then

{(\frac{ψ (l)}{κ (l_{1}, l)})}^{'} \leq 0, f o r l \geq l_{1} .

(7)

Proof.

Assume that (1) has a positive solution y on

[l_{0}, \infty)

. Therefore, there exists a

l_{1} \geq l_{0}

such that, for all

l \geq l_{1}

,

ψ (l) \geq y (l) > 0

and

(r (l) {(ψ^{'} (l))}^{γ}) \leq 0

. From (1), we see that

{(r (l) {(ψ^{'} (l))}^{γ})}^{'} = - q (l) y^{γ} (σ (l)) \leq 0 .

Obviously,

ψ

is either eventually decreasing or eventually increasing.

Let

ψ

be a decreasing function on

[l_{1}, \infty) .

Then,

{lim}_{l \to \infty} ψ (l) < \infty

, and so

ψ (l) \geq - \int_{l}^{\infty} r^{- 1 / γ} (ϑ) r^{1 / γ} (ϑ) ψ^{'} (ϑ) d ϑ \geq - κ (l, \infty) r^{1 / γ} (l) ψ^{'} (l) .

(8)

Thus,

{(\frac{ψ (l)}{κ (l, \infty)})}^{'} = \frac{κ (l, \infty) ψ^{'} (l) + r^{- 1 / γ} (l) ψ (l)}{{(κ (l, \infty))}^{2}} \geq 0 .

Let

ψ

be a increasing function on

[l_{1}, \infty)

. Then, we obtain

ψ (l) \geq \int_{l_{1}}^{l} r^{- 1 / γ} (ϑ) r^{1 / γ} (ϑ) ψ^{'} (ϑ) d ϑ \geq κ (l_{1}, l) r^{1 / γ} (l) ψ^{'} (l),

and so

{(\frac{ψ (l)}{κ (l_{1}, l)})}^{'} = \frac{κ (l_{1}, l) ψ^{'} (l) - r^{- 1 / γ} (l) ψ (l)}{κ^{2} (l_{1}, l)} \leq 0 .

Thus, the proof is complete. □

Theorem 1.

Assume that

B_{2} (l) \geq B_{1} (l) > 0

. If

\underset{l \to \infty}{lim sup} \int_{l_{1}}^{l} \frac{1}{r^{1 / γ} (β)} {(\int_{l_{1}}^{β} q (δ) B_{1}^{γ} (σ (δ)) κ^{γ} (σ (δ), \infty) d δ)}^{1 / γ} d β = \infty,

(9)

then, all solutions of (1) are oscillatory.

Proof.

Assume the contrary that Equation (1) has a positive solution y on

[l_{0}, \infty)

. Then,

y (ρ_{1} (l))

,

y (ρ_{2} (l))

and

y (σ (l))

are positive for all

l \geq l_{1},

where

l_{1}

is large enough. Thus, from (1) and the definition of

ψ

, we note that

ψ (l) \geq y (l) > 0

and

r (l) {(ψ^{'} (l))}^{γ}

is nonincreasing. Therefore,

ψ^{'}

is either eventually negative or eventually positive.

Let

ψ^{'} (l) < 0

on

[l_{1}, \infty)

. By using Lemma 2, we have

ψ (ρ_{1} (l)) \leq \frac{κ (ρ_{1} (l), \infty)}{κ (l, \infty)} ψ (l),

based on the fact that

ρ_{1} (l) \leq l

. Therefore,

\begin{matrix} y (l) & = & ψ (l) - p_{1} (l) y (ρ_{1} (l)) - p_{2} (l) y (ρ_{2} (l)) \\ \geq & ψ (l) - p_{1} (l) ψ (ρ_{1} (l)) - p_{2} (l) ψ (ρ_{2} (l)) \\ \geq & (1 - p_{1} (l) \frac{κ (ρ_{1} (l), \infty)}{κ (l, \infty)} - p_{2} (l)) ψ (l) \\ = & B_{1} (l) ψ (l) . \end{matrix}

Therefore, (1) becomes

{(r (l) {(ψ^{'} (l))}^{γ})}^{'} \leq - q (l) B_{1}^{γ} (σ (l)) ψ^{γ} (σ (l)) .

(10)

As

{(r (l) {(ψ^{'} (l))}^{γ})}^{'} \leq 0

, we have

r (l) {(ψ^{'} (l))}^{γ} \leq r (l_{1}) {(ψ^{'} (l_{1}))}^{γ} : = - L < 0,

(11)

for all

l \geq l_{1},

from (8) and (11), we have

ψ^{γ} (l) \geq L κ^{γ} (l, \infty) for all l \geq l_{1} .

(12)

Combining (10) with (12) yields

{(r (l) {(ψ^{'} (l))}^{γ})}^{'} \leq - L q (l) B_{1}^{γ} (σ (l)) κ^{γ} (σ (l), \infty),

(13)

for all

l \geq l_{1}

. Integrating (13) from

l_{1}

to l, we obtain

\begin{matrix} r (l) {(ψ^{'} (l))}^{γ} & \leq & r (l_{1}) {(ψ^{'} (l_{1}))}^{γ} - L \int_{l_{1}}^{l} q (δ) B_{1}^{γ} (σ (δ)) κ^{γ} (σ (δ), \infty) d δ \\ \leq & - L \int_{l_{1}}^{l} q (δ) B_{1}^{γ} (σ (δ)) κ^{γ} (σ (δ), \infty) d δ . \end{matrix}

Integrating the last inequality from

l_{1}

to l, we get

ψ (l) \leq ψ (l_{1}) - L^{1 / γ} \int_{l_{1}}^{l} \frac{1}{r^{1 / γ} (β)} {(\int_{l_{1}}^{β} q (δ) B_{1}^{γ} (σ (δ)) κ^{γ} (σ (δ), \infty) d δ)}^{1 / γ} d β .

At

l \to \infty

, we get a contradiction with (9).

Let

ψ^{'} (l) > 0

on

[l_{1}, \infty)

. From Lemma 2, we arrive at

ψ (ρ_{2} (l)) \leq \frac{κ (l_{1}, ρ_{2} (l))}{κ (l_{1}, l)} ψ (l) .

(14)

From the definition of

ψ

, we obtain

\begin{matrix} y (l) & = & ψ (l) - p_{1} (l) y (ρ_{1} (l)) - p_{2} (l) y (ρ_{2} (l)) \\ \geq & ψ (l) - p_{1} (l) ψ (ρ_{1} (l)) - p_{2} (l) ψ (ρ_{2} (l)) . \end{matrix}

(15)

Using that (14) and

ψ (ρ_{1} (l)) \leq ψ (l)

where

ρ_{1} (l) < l

in (15), we obtain

\begin{matrix} y (l) & \geq & ψ (l) (1 - p_{1} (l) - p_{2} (l) \frac{κ (l_{1}, ρ_{2} (l))}{κ (l_{1}, l)}) \\ \geq & B_{2} (l) ψ (l) . \end{matrix}

(16)

Thus, (1) becomes

{(r (l) {(ψ^{'} (l))}^{γ})}^{'} \leq - q (l) B_{2}^{γ} (σ (l)) ψ^{γ} (σ (l)) .

(17)

Now, from (9) and (C2), we have that

\int_{l_{1}}^{l} q (ϑ) B_{1}^{γ} (σ (ϑ)) κ^{γ} (σ (ϑ), \infty) d ϑ

is unbounded. Therefore, as

κ^{'} (l, \infty) < 0

, we obtain that

\int_{l_{1}}^{l} q (ϑ) B_{1}^{γ} (σ (ϑ)) d ϑ \to \infty as l \to \infty .

(18)

Integrating (17) from

l_{2}

to l, we get

\begin{matrix} r (l) {(ψ^{'} (l))}^{γ} & \leq & r (l_{2}) {(ψ^{'} (l_{2}))}^{γ} - \int_{l_{2}}^{l} q (ϑ) B_{2}^{γ} (σ (ϑ)) ψ^{γ} (σ (ϑ)) d ϑ \\ \leq & r (l_{2}) {(ψ^{'} (l_{2}))}^{γ} - ψ^{γ} (σ (l_{2})) \int_{l_{2}}^{l} q (ϑ) B_{2}^{γ} (σ (ϑ)) d ϑ . \end{matrix}

As

B_{2} (l) > B_{1} (l)

, we get

r (l) {(ψ^{'} (l))}^{γ} \leq r (l_{2}) {(ψ^{'} (l_{2}))}^{γ} - ψ^{γ} (σ (l_{2})) \int_{l_{2}}^{l} q (ϑ) B_{1}^{γ} (σ (ϑ)) d ϑ .

(19)

From (18) and (19), we get a contradiction with the positivity of

ψ^{'} (l)

. Therefore, the proof is complete. □

Theorem 2.

Assume that

B_{2} (l) \geq B_{1} (l) > 0

. If

\underset{l \to \infty}{lim sup} κ^{γ} (l, \infty) \int_{l_{1}}^{l} q (ϑ) B_{1}^{γ} (ϑ) d ϑ > 1,

(20)

then, all solutions of (1) are oscillatory.

Proof.

Assume the contrary that Equation (1) has a positive solution y on

[l_{0}, \infty)

. Then,

y (ρ_{1} (l))

,

y (ρ_{2} (l))

and

y (σ (l))

are positive for all

l \geq l_{1},

where

l_{1}

is large enough. Thus, from (1) and the definition of

ψ

, we note that

ψ (l) \geq y (l) > 0

and

r (l) {(ψ^{'} (l))}^{γ}

is nonincreasing. Therefore,

ψ^{'}

is either eventually negative or eventually positive.

Let

ψ^{'} (l) < 0

on

[l_{1}, \infty)

. Integrating (10) from

l_{1}

to l, we get

\begin{matrix} r (l) {(ψ^{'} (l))}^{γ} & \leq & r (l_{1}) {(ψ^{'} (l_{1}))}^{γ} - \int_{l_{1}}^{l} q (ϑ) B_{1}^{γ} (σ (ϑ)) ψ^{γ} (σ (ϑ)) d ϑ \\ \leq & - ψ^{γ} (σ (l)) \int_{l_{1}}^{l} q (ϑ) B_{1}^{γ} (ϑ) d ϑ . \end{matrix}

(21)

Using

ψ (σ (l)) \geq ψ (l)

and (8) in (21), we obtain

- r (l) {(ψ^{'} (l))}^{γ} \geq - r (l) {(ψ^{'} (l))}^{γ} κ^{γ} (l, \infty) \int_{l_{1}}^{l} q (ϑ) B_{1}^{γ} (ϑ) d ϑ .

(22)

Divide both sides of inequality (22) by

- r (l) {(ψ^{'} (l))}^{γ}

and taking the limsup, we get

\underset{l \to \infty}{lim sup} κ^{γ} (l, \infty) \int_{l_{1}}^{l} q (ϑ) B_{1}^{γ} (ϑ) d ϑ \leq 1 .

Thus, we get a contradiction with (20).

Let

ψ^{'} > 0

on

[l_{1}, \infty) .

From (20) and the fact that

κ (l, \infty) < \infty

, we have that (18) holds. Then, this part of proof is similar to that of Theorem 1. Therefore, the proof is complete. □

Theorem 3.

Assume that

B_{2} (l) > 0,

B_{1} (l) > 0

and

r^{'} > 0

. If there exist positive functions

μ, δ \in C^{1} ([l_{0}, \infty))

and

l_{1} \in [l_{0}, \infty)

such that

\underset{l \to \infty}{lim sup} \{\frac{κ^{γ} (l, \infty)}{δ (l)} \int_{l_{1}}^{l} (δ (ϑ) q (ϑ) B_{1}^{γ} (σ (ϑ)) - \frac{r (ϑ)}{{(γ + 1)}^{γ + 1}} \frac{{(δ^{'} (ϑ))}^{γ + 1}}{{(δ (ϑ))}^{γ}}) d ϑ\} > 1

(23)

and

\underset{l \to \infty}{lim sup} \int_{l_{1}}^{l} (μ (ϑ) q (ϑ) B_{2}^{γ} (σ (ϑ)) - \frac{1}{{(γ + 1)}^{γ + 1}} \frac{r (ϑ) {(μ^{'} (ϑ))}^{γ + 1}}{μ^{γ} (ϑ) {(σ^{'} (ϑ))}^{γ}}) d ϑ = \infty,

(24)

then, all solutions of (1) are oscillatory.

Proof.

Assume the contrary that Equation (1) has a positive solution y on

[l_{0}, \infty)

. Then,

y (ρ_{1} (l))

,

y (ρ_{2} (l))

and

y (σ (l))

are positive for all

l \geq l_{1},

where

l_{1}

is large enough. Thus, from (1) and the definition of

ψ

, we note that

ψ (l) \geq y (l) > 0

and

r (l) {(ψ^{'} (l))}^{γ}

is nonincreasing. Therefore,

ψ^{'}

is either eventually negative or eventually positive.

Let

ψ^{'} < 0

on

[l_{1}, \infty) .

As in proof of Theorem 1, we arrive at (10). Now, we define the function

ω (l) = δ (l) (\frac{r (l) {(ψ^{'} (l))}^{γ}}{ψ^{γ} (l)} + \frac{1}{κ^{γ} (l, \infty)}) on [l_{1}, \infty) .

(25)

From (8), we have that

ω \geq 0

on

[l_{1}, \infty) .

Differentiating (25), we get

\begin{matrix} ω^{'} (l) & = & \frac{δ^{'} (l)}{δ (l)} ω (l) + δ (l) \frac{{(r (l) {(ψ^{'} (l))}^{γ})}^{'}}{ψ^{γ} (l)} - γ δ (l) r (l) {(\frac{ψ^{'} (l)}{ψ (l)})}^{γ + 1} \\ + \frac{γ δ (l)}{r^{1 / γ} (l) κ^{γ + 1} (l, \infty)} \\ \leq & \frac{δ^{'} (l)}{δ (l)} ω (l) + δ (l) \frac{{(r (l) {(ψ^{'} (l))}^{γ})}^{'}}{ψ^{γ} (l)} - \frac{γ}{{(δ (l) r (l))}^{1 / γ}} {(ω (l) - \frac{δ (l)}{κ^{γ} (l, \infty)})}^{(γ + 1) / γ} \\ + \frac{γ δ (l)}{r^{1 / γ} (l) κ^{γ + 1} (l, \infty)} . \end{matrix}

(26)

Combining (10) and (26), we have

\begin{matrix} ω^{'} (l) & \leq & - \frac{γ}{{(δ (l) r (l))}^{1 / γ}} {(ω (l) - \frac{δ (l)}{κ^{γ} (l, \infty)})}^{(γ + 1) / γ} - δ (l) q (l) B_{1}^{γ} (σ (l)) \frac{ψ^{γ} (σ (l))}{ψ^{γ} (l)} \\ + \frac{γ δ (l)}{r^{1 / γ} (l) κ^{γ + 1} (l, \infty)} + \frac{δ^{'} (l)}{δ (l)} ω (l) . \end{matrix}

(27)

Using Lemma 1 with

A : = δ^{'} (l) / δ (l)

,

B : = γ {(δ (l) r (l))}^{- 1 / γ}

,

C : = δ (l) / κ^{γ} (l, \infty)

and

ϑ : = ω

, we get

\begin{matrix} \frac{δ^{'} (l)}{δ (l)} ω (l) - \frac{γ}{{(δ (l) r (l))}^{1 / γ}} {(ω (l) - \frac{δ (l)}{κ^{γ} (l, \infty)})}^{(γ + 1) / γ} & \leq & \frac{1}{{(γ + 1)}^{γ + 1}} r (l) \frac{{(δ^{'} (l))}^{γ + 1}}{{(δ (l))}^{γ}} \\ + \frac{δ^{'} (l)}{κ^{γ} (l, \infty)} . \end{matrix}

As

l \geq σ (l)

, we arrive at

ψ (σ (l)) \geq ψ (l),

(28)

which, in view of (27) and (28), gives

\begin{matrix} ω^{'} (l) & \leq & \frac{δ^{'} (l)}{κ^{γ} (l, \infty)} + \frac{1}{{(γ + 1)}^{γ + 1}} r (l) \frac{{(δ^{'} (l))}^{γ + 1}}{{(δ (l))}^{γ}} - δ (l) q (l) B_{1}^{γ} (σ (l)) \frac{ψ^{γ} (σ (l))}{ψ^{γ} (l)} \\ + \frac{γ δ (l)}{r^{1 / γ} (l) κ^{γ + 1} (l, \infty)} \\ \leq & - δ (l) q (l) B_{1}^{γ} (σ (l)) + {(\frac{δ (l)}{κ^{γ} (l, \infty)})}^{'} + \frac{r (l)}{{(γ + 1)}^{γ + 1}} \frac{{(δ^{'} (l))}^{γ + 1}}{{(δ (l))}^{γ}} . \end{matrix}

(29)

Integrating (29) from

l_{2}

to

l,

we arrive at

\begin{matrix} \int_{l_{2}}^{l} (δ (ϑ) q (ϑ) B_{1}^{γ} (σ (ϑ)) - \frac{r (ϑ)}{{(γ + 1)}^{γ + 1}} \frac{{(δ^{'} (ϑ))}^{γ + 1}}{{(δ (ϑ))}^{γ}}) d ϑ & \leq & {(\frac{δ (l)}{κ^{γ} (l, \infty)} - ω (l))}_{l_{2}}^{l} \\ \leq & - {(δ (l) \frac{r (l) {(ψ^{'} (l))}^{γ}}{ψ^{γ} (l)})}_{l_{2}}^{l} . \end{matrix}

(30)

From (8), we have

- \frac{r^{1 / γ} (l) ψ^{'} (l)}{ψ (l)} \leq \frac{1}{κ (l, \infty)},

which, in view of (30), implies

\frac{κ^{γ} (l, \infty)}{δ (l)} \int_{l_{2}}^{l} (δ (ϑ) q (ϑ) B_{1}^{γ} (σ (ϑ)) - \frac{r (ϑ)}{{(γ + 1)}^{γ + 1}} \frac{{(δ^{'} (ϑ))}^{γ + 1}}{{(δ (ϑ))}^{γ}}) d ϑ \leq 1 .

Thus, we get a contradiction with (23).

Let

ψ^{'} (l) > 0

on

[l_{1}, \infty)

. As in proof of Theorem 1, we arrive at (17). Now, we define the function

φ (l) = μ (l) \frac{r (l) {(ψ^{'} (l))}^{γ}}{ψ^{γ} (σ (l))} .

(31)

Therefore, we have that

ω \geq 0

on

[l_{1}, \infty) .

Differentiating (31), we find

φ^{'} (l) = \frac{μ^{'} (l)}{μ (l)} φ (l) + μ (l) \frac{{(r (l) {(ψ^{'} (l))}^{γ})}^{'}}{ψ^{γ} (σ (l))} - γ μ (l) r (l) \frac{{(ψ^{'} (l))}^{γ} ψ^{'} (σ (l)) σ^{'} (l)}{ψ^{γ + 1} (σ (l))} .

(32)

Combining (17) and (32), we have

φ^{'} (l) \leq \frac{μ^{'} (l)}{μ (l)} φ (l) - μ (l) q (l) B_{2}^{γ} (σ (l)) - γ μ (l) r (l) \frac{{(ψ^{'} (l))}^{γ} ψ^{'} (σ (l)) σ^{'} (l)}{ψ^{γ + 1} (σ (l))} .

As

{(r (l) {(ψ^{'} (l))}^{γ})}^{'} < 0

and

σ (l) \leq l,

we arrive at

φ^{'} (l) \leq \frac{μ^{'} (l)}{μ (l)} φ (l) - μ (l) q (l) B_{2}^{γ} (σ (l)) - γ μ (l) r (l) σ^{'} (l) \frac{{(ψ^{'} (l))}^{γ + 1}}{ψ^{γ + 1} (σ (l))} .

From (31), we have

φ^{'} (l) \leq \frac{μ^{'} (l)}{μ (l)} φ (l) - μ (l) q (l) B_{2}^{γ} (σ (l)) - \frac{γ σ^{'} (l)}{μ^{1 / γ} (l) r^{1 / γ} (l)} ϕ^{(γ + 1) / γ} (l) .

Using the inequality

K v - L v^{^{(γ + 1) / γ}} \leq \frac{γ^{γ}}{{(γ + 1)}^{γ + 1}} \frac{K^{γ + 1}}{L^{γ}}, L > 0,

(33)

with

K = μ^{'} (l) / μ (l),

L = γ σ^{'} (l) / μ^{1 / γ} (l) r^{1 / γ} (l)

and

v = φ,

we have

φ^{'} (l) \leq - μ (l) q (l) B_{2}^{γ} (σ (l)) + \frac{1}{{(γ + 1)}^{γ + 1}} \frac{r (l) {(μ^{'} (l))}^{γ + 1}}{μ^{γ} (l) {(σ^{'} (l))}^{γ}} .

(34)

Integrating (34) from

l_{2}

to

l,

we arrive at

\int_{l_{2}}^{l} (μ (ϑ) q (ϑ) B_{2}^{γ} (σ (ϑ)) - \frac{1}{{(γ + 1)}^{γ + 1}} \frac{r (ϑ) {(μ^{'} (ϑ))}^{γ + 1}}{μ^{γ} (ϑ) {(σ^{'} (ϑ))}^{γ}}) d ϑ \leq φ (l_{2}) .

Taking the lim sup on both sides of this inequality, we have a contradiction with (24). The proof of the theorem is complete. □

Example 1.

Consider the second-order neutral differential equation

{(l^{2} ({(y (l) + p_{0} y (\frac{l}{λ}) + p_{*} y (λ l))}^{'}))}^{'} + q_{0} l y (σ_{0} l) = 0,

(35)

where

λ > 1

,

σ_{0} \in (0, 1)

and

(λ p_{0} + p_{*}) \in (0, 1) .

We note that

r (l) = l^{2}

,

p_{1} (l) = p_{0}

,

p_{2} (l) = p_{*}

,

ρ_{1} (l) = l / λ

,

ρ_{2} (l) = λ l

,

q (l) = q_{0} l

and

σ (l) = σ_{0} l

. It is easy to verify that

B_{1} (l) = 1 - λ p_{0} - p_{*},

and

B_{2} (l) = 1 - p_{0} - p_{*} (\frac{l - \frac{1}{λ}}{l - 1}),

and so

B_{2} > B_{1} > 0

. Now, we see that

\begin{matrix} \underset{l \to \infty}{lim sup} \int_{l_{1}}^{l} \frac{1}{r^{1 / γ} (β)} {(\int_{l_{1}}^{β} q (δ) B_{1}^{γ} (σ (δ)) κ^{γ} (σ (δ), \infty) d δ)}^{1 / γ} d β \\ = \underset{l \to \infty}{lim sup} \int_{l_{1}}^{l} \frac{1}{β^{2}} (\int_{l_{1}}^{β} q_{0} δ (1 - λ p_{0} - p_{*}) \frac{1}{σ_{0} δ} d δ) d β = \infty . \end{matrix}

Then, by Theorem 1, we have that (35) is oscillatory.

3. Conclusions

In this work, new criteria to test the oscillation of the solutions of second-order non-canonical neutral differential equations with mixed type were presented. These criteria are to further complement and simplify relevant results in the literature.

Author Contributions

Conceptualization, O.M. and Y.S.H.; methodology, H.A.; investigation, O.M. and A.N.; writing—original draft preparation, O.M., A.N. and Y.S.H.; writing—review and editing, A.N. and H.A. All authors have read and agreed to the published version of the manuscript.

Funding

There is no external funding for this article.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

Not applicable.

Acknowledgments

This research was supported by Taif University Researchers Supporting Project Number (TURSP-2020/155), Taif University, Taif, Saudi Arabia.

Conflicts of Interest

The authors declare no conflict of interest.

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Moaaz, O.; Nabih, A.; Alotaibi, H.; Hamed, Y.S. Second-Order Non-Canonical Neutral Differential Equations with Mixed Type: Oscillatory Behavior. Symmetry 2021, 13, 318. https://0-doi-org.brum.beds.ac.uk/10.3390/sym13020318

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Moaaz O, Nabih A, Alotaibi H, Hamed YS. Second-Order Non-Canonical Neutral Differential Equations with Mixed Type: Oscillatory Behavior. Symmetry. 2021; 13(2):318. https://0-doi-org.brum.beds.ac.uk/10.3390/sym13020318

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Moaaz, Osama, Amany Nabih, Hammad Alotaibi, and Y. S. Hamed. 2021. "Second-Order Non-Canonical Neutral Differential Equations with Mixed Type: Oscillatory Behavior" Symmetry 13, no. 2: 318. https://0-doi-org.brum.beds.ac.uk/10.3390/sym13020318

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Second-Order Non-Canonical Neutral Differential Equations with Mixed Type: Oscillatory Behavior

Abstract

1. Introduction

2. Main Results

3. Conclusions

Author Contributions

Funding

Institutional Review Board Statement

Informed Consent Statement

Data Availability Statement

Acknowledgments

Conflicts of Interest

References

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