A DDE is a single-variable differential equation, usually called time, in which the derivative of the solution at a certain time is given in terms of the values of the solution at earlier times. Moreover, if the highest-order derivative of the solution appears both with and without delay, then the DDE is called of the neutral type. The neutral DDEs have many interesting applications in various branches of applied science, as these equations appear in the modeling of many technological phenomena. The problem of studying the oscillatory and nonoscillatory properties of DDEs has been a very active area of research in the past few decades.
1. Introduction
Consider the 2nd-order delay differential equation (DDE) of the neutral type:
(
1
)
where
and
. In this entry, we obtain new sufficient criteria for the oscillation of solutions of (1) under the following hypotheses:
(A1) is a ratio of odd integers;
(A2)
for
a constant (this constant plays an important role in the results), and
does not vanish identically on any half-line
with
(A3)
and
for
By a proper solution of (1), we mean a
with
and
for
and u satisfies (1) on . A solution u of (1) is called nonoscillatory if it is eventually positive or eventually negative; otherwise, it is called oscillatory. and u satisfies (1) on . A solution u of (1) is called nonoscillatory if it is eventually positive or eventually negative; otherwise, it is called oscillatory.
The oscillatory properties of solutions of second-order neutral DDE (1) in the noncanonical case, that is:
(
2
)
where
2. Oscillatory Properties of Noncanonical Neutral DDEs of Second-Order
We begin with the following notations: is the set of all eventually positive solutions of (1), ,
Lemma 1. Assume that and there exists a such that:
Then, v eventually satisfies:
and: