1 Introduction

The differential equations that we study describe many phenomena and dynamical processes in various fields, and they have attracted a great deal of attention of researchers in physical sciences, mathematics, biology, and economy. In addition, these equations play an important role in numerical simulations of nonlinear partial differential equations, queuing problems, and discretization in solid state and quantum physics. For the application, please see [1].

In this paper, we consider the oscillation of second order nonlinear neutral differential equations with mixed type term of the form

$$ \bigl(a(t) \bigl(x(t)+ \delta p(t)x(t-\tau)\bigr)' \bigr)'+f\bigl(t,x(t-\sigma)\bigr)-g\bigl(t,x(t-\rho)\bigr)=0, $$
(1.1)

where \(\delta=+1 \mbox{ or }{-}1\), \(t\ge t_{0}\), \(a(t)\) is a continuously differentiable function, \(p(t)\) is a continuous bounded function with \(a(t)>0\), \(p(t)\ge0\), \(f(t,u)\) and \(g(t,v)\) are continuous functions, the constants \(\tau, \sigma, \rho \in[0, \infty)\). Denote \(\lambda =\max\{\tau,\sigma,\rho\}\), \(t_{1}=t_{0}+\lambda\), \(L^{1}[t_{0}, \infty)= \{x(t)| \int_{t_{0}}^{\infty}|x(s)|\,ds<\infty \}\).

The following conditions will be assumed throughout this paper:

(H1):

\(\int_{t}^{\infty}\frac{1}{a(s)}\,ds=\infty\) for all \(t\geq t_{0} \),

(H2):

\(\frac{f(t,u)}{u}\geq q(t-\sigma)>0\) for \(u\neq0\) and \(0<\frac{g(t,v)}{v}\leq r(t-\rho)\) for \(v\neq0\),

(H3):

\(0<\frac{f(t,u)}{u}\leq q(t-\sigma)\) for \(u\neq0\) and \(\frac{g(t,v)}{v}\geq r(t-\rho)>0 \) for \(v\neq 0\),

(H4):

\(\frac{1}{r(t)-q(t)}\) is bounded, where \(q,r \in C([t_{0},\infty),R^{+})\).

We also assume that \(x(t)\) is a nontrivial solution of (1.1). The investigation of oscillatory behavior of solutions of various types of differential equations done by many researchers is motivated by many application problems in physics, biology, ecology, and so on. In particular, an increasing interest in obtaining oscillation criteria for different classes of differential and functional differential equations has been manifested recently. Please see [116].

The paper is organized as follows. We will first present criteria for (1.1) when \(\delta=+1\) in Section 2 and then for (1.1) when \(\delta=-1\) in Section 3. Some examples will be given to illustrate the obtained criteria, respectively. The proofs of the main results are left to Section 4.

2 Statement of the main results when \(\delta=+1\)

We first rewrite (1.1) as

$$ \bigl(a(t) \bigl(x(t)+ p(t)x(t-\tau)\bigr)' \bigr)'+f\bigl(t,x(t-\sigma)\bigr)-g\bigl(t,x(t-\rho)\bigr)=0. $$
(2.1)

In this section, four oscillatory criteria will be presented and some illustrated examples will be given.

Theorem 2.1

Suppose that conditions (H1), (H2) and (H4) hold, \(q(t)>r(t)\), \(r(t)\) is bounded and \(\sigma\geq\rho\). Then (2.1) is bounded oscillatory.

Remark 2.2

In [16], the authors considered

$$\bigl(x(t)+p(t)x\bigl(\tau(t)\bigr)\bigr)^{(n)}+q(t)f\bigl(x\bigl( \sigma(t)\bigr)\bigr)=0 $$

and established the criteria for the solution to be oscillatory when \(0 \leq p(t) <1\). Even though this result is about the higher order equations, the generality of our results is not robbed since our equations include a larger class of equations.

Example 1

Consider the differential equation

$$\begin{aligned} &\biggl( \biggl(1+\frac{1}{t} \biggr) \bigl(x(t)+2x(t-2\pi) \bigr)' \biggr)' + 3 \biggl(1+\frac{1}{t} \biggr)x(t-2\pi) \\ &\quad{}+3 \biggl(1+\frac{1}{t} \biggr)x^{5}(t-2{\pi}) - \frac {3}{t^{2}}x \biggl(t-\frac{\pi}{2} \biggr)=0. \end{aligned}$$
(2.2)

Viewing (2.2) as (2.1), we have \(a(t)=1+(1/t)\), \(p(t)=2>0\), and

$$q(t)=3 \biggl(1+\frac{1}{t+2\pi} \biggr)>r(t)=\frac{3}{ (t+\frac{\pi}{2} )^{2}}. $$

Moreover, \(\tau=2\pi\), \(\sigma=2\pi>\rho=\pi/2\), and \(r(t)\) is bounded for \(t \geq2\pi\). Note that conditions (H1), (H2) and (H4) are satisfied and, by Theorem 2.1, (2.2) is bounded oscillatory.

Theorem 2.3

Suppose that conditions (H1), (H2) and (H4) hold, \(q(t)>r(t)\), \(q(t)\), \(1/a(t)\) are bounded and \(\sigma<\rho\). Then (2.1) is almost oscillatory.

Example 2

Consider the differential equation

$$ \bigl(t\bigl(x(t)+x(t-\pi)\bigr)' \bigr)'+ \frac{t\pi}{t-2\pi} x(t-2\pi)-\frac{\pi}{t-\frac{7}{2}\pi}x \biggl(t- \frac{7}{2}\pi \biggr)=0. $$
(2.3)

Viewing (2.3) as (2.1), we have \(a(t)=t\), \(p(t)=1>0\), and

$$q(t)= \frac{(t+2\pi)\pi}{t}>r(t)=\frac{\pi}{t}. $$

Moreover, \(\tau=\pi\), \(\sigma=2\pi<\rho=7\pi/2\), \(q(t)\) is bounded for \(t \geq4\pi\). Note that conditions (H1), (H2) and (H4) are satisfied. By Theorem 2.3, (2.3) is almost oscillatory. Indeed, \(x(t)=t\sin t\) is an unbounded oscillatory solution of (2.3).

Theorem 2.4

Suppose that conditions (H1), (H3) and (H4) hold, \(q(t)< r(t)\), \(r(t)\), \(1/a(t)\) are bounded and \(\sigma\geq\rho\). Then (2.1) is bounded almost oscillatory.

Theorem 2.5

Suppose that conditions (H1), (H3) and (H4) hold, \(q(t)< r(t)\), \(q(t)\) is bounded and \(\sigma< \rho\). Then (2.1) is bounded almost oscillatory.

Example 3

Consider the differential equation

$$\begin{aligned} &\biggl(\frac{t+1-3\pi}{t-3\pi} \biggl(x(t)+\frac{t-\pi}{t(t+1-\pi)}x(t-\pi ) \biggr)' \biggr)' \\ &\quad{}+\frac{2t+2-3\pi}{(t-3\pi)(2t-3\pi)}x \biggl(t-\frac{3\pi}{2} \biggr)-x(t-3\pi) = 0. \end{aligned}$$
(2.4)

Viewing (2.4) as (2.1), we have

$$\begin{aligned}& a(t)=\frac{t+1-3\pi}{t-3\pi},\\& p(t)=\frac{t-\pi}{t(t+1-\pi)}>0,\\& q(t)=\frac{2t+2}{t(2t-3\pi)}< r(t)= 1. \end{aligned}$$

Also,

$$\tau=\pi, \sigma=\frac{3\pi}{2}< \rho=3\pi \mbox{ and } q(t) \mbox{ is bounded for } t \geq3\pi. $$

We note that conditions (H1), (H3) and (H4) are satisfied and, by Theorem 2.5, (2.4) is bounded almost oscillatory. In fact, \(x(t)=(1+(1/t))\sin t\) is a bounded oscillatory solution of (2.4).

3 Statement of the main results when \(\delta=-1\)

In this section, we consider (1.1) when \(\delta=-1\). So (1.1) becomes

$$ \bigl(a(t) \bigl(x(t)- p(t)x(t-\tau)\bigr)' \bigr)'+f\bigl(t,x(t-\sigma)\bigr)-g\bigl(t,x(t-\rho)\bigr)=0. $$
(3.1)

Four oscillation criteria have been obtained. In addition, some example will be given to demonstrate the obtained results.

Theorem 3.1

Suppose that conditions (H1), (H3) and (H4) hold, \(p(t)\ge1\), \(q(t)< r(t)\), \(\sigma\le\rho\) and \(r(t)\) is bounded. Then (3.1) is bounded oscillatory.

Example 4

Consider the differential equation

$$ \biggl( \biggl(1-\frac{1}{t} \biggr) \bigl(x(t)-2x(t-\pi) \bigr)' \biggr)'+ \frac{3}{t^{2}}x \biggl(t- \frac{\pi}{2} \biggr)-3x(t-\pi)=0. $$
(3.2)

Viewing (3.2) as (3.1), we have \(\tau=\pi\), \(\sigma=\frac{\pi}{2}<\rho=\pi\),

$$\begin{aligned}& a(t)=1-\frac{1}{t},\\& p(t)=2>0,\\& q(t)=\frac{3}{ (t+\frac{\pi}{2} )^{2}}< r(t)=3 \end{aligned}$$

for \(t\ge\pi\). We note that conditions (H1), (H3) and (H4) are satisfied and, by Theorem 3.1, (3.2) is bounded oscillatory.

Theorem 3.2

Suppose that conditions (H1), (H3) and (H4) hold, \(q(t)< r(t)\), \(\sigma\ge \rho\), \(0\le p(t)\le p_{1}<1\) or \(1< p_{2}\le p(t)\), \(r(t)\) and \(1/a(t)\) are bounded. Then (3.1) is bounded almost oscillatory.

Theorem 3.3

Suppose that conditions (H1), (H2) and (H4) hold, \(q(t)>r(t)\), \(\sigma<\rho\), \(0\le p(t)\le p_{1}<1\) or \(1< p_{2}\le p(t)\), \(q(t)\) and \(1/a(t)\) are bounded. Then (3.1) is bounded almost oscillatory.

Example 5

Consider the differential equation

$$\begin{aligned} &\biggl(\frac{t}{t+1} \biggl(x(t)-\frac{2(t-2\pi)}{t}x(t-2 \pi) \biggr)' \biggr)'+ \frac{(t^{3}+t^{2}-2t-1)(t-\pi)}{2t^{2}(t+1)^{2}}x(t-\pi) \\ &\quad{} -\frac{(2t+1) (t-\frac{3\pi}{2} )}{2t(t+1)^{2}}x \biggl(t-\frac{3\pi}{2} \biggr)=0. \end{aligned}$$
(3.3)

Viewing (3.3) as (3.1), we have \(\tau=2\pi\), \(\sigma =\pi<\rho=3\pi/2\),

$$\begin{aligned}& a(t)=\frac{t}{t+1},\\& p(t)=\frac{2(t-2\pi)}{t}\ge 1.2 \quad\mbox{for } t\ge5\pi,\\& q(t)=\frac{t((t+\pi)^{3}+(t+\pi)^{2}-2t-2\pi-1)}{2(t+\pi)^{2}(t+\pi+1)^{2}},\\& r(t)=\frac{t(2t+3\pi+1)}{2(t+3\pi/2)(t+3\pi/2+1)^{2}}. \end{aligned}$$

Clearly, \(q(t)>r(t)\) for large t and \(1/a(t)\) and \(q(t) \) are bounded. We note that conditions (H1), (H2) and (H4) are satisfied and, by Theorem 3.3, (3.3) is bounded almost oscillatory.

Theorem 3.4

Suppose that conditions (H1), (H2) and (H4) hold, \(q(t)>r(t)\), \(\sigma \ge\rho\), \(q(t)\) is bounded, \(0\le p(t)\le p_{1}<1\), or \(1/a(t)\) is bounded and \(1< p_{2}\le p(t)\). Then (3.1) is bounded almost oscillatory.

Example 6

Consider the differential equation

$$\begin{aligned} &\biggl(\frac{t}{t+1} \biggl(x(t)-\frac{t-2\pi}{2t}x(t-2\pi) \biggr)' \biggr)' + \frac{(t^{3}+t^{2}-2t-1)(t-2\pi )}{2t^{2}(t+1)^{2}}x(t-2\pi) \\ &\quad{}- \frac{(2t+1)(t-\pi/2)}{2t(t+1)^{2}}x(t-\pi/2)=0. \end{aligned}$$
(3.4)

Regarding (3.4) as (3.1), we have \(\tau=2\pi\), \(\sigma=2\pi>\rho=\frac{\pi}{2}\),

$$\begin{aligned}& a(t)=\frac{t}{t+1},\\& 0< p(t)=\frac{t-2\pi}{2t}\le \frac{1}{2}<1,\quad t \geq3\pi,\\& q(t)=\frac{t((t+2\pi)^{3}+(t+2\pi)^{2}-2t-4\pi-1)}{2(t+2\pi)^{2}(t+2\pi +1)^{2}},\\& r(t)=\frac{t(2t+\pi+1)}{2(t+\pi/2)(t+\pi/2+1)^{2}}. \end{aligned}$$

Clearly, \(q(t)>r(t)\) for large enough t and \(q(t)\) is bounded. Notice that (H1), (H2) and (H4) are satisfied therefore, by Theorem 3.4, (3.4) is bounded almost oscillatory.

4 Proofs of the main results

Here we will give the proofs of the main results.

Proof of Theorem 2.1

Let \(x(t)\) be a bounded non-oscillatory solution. Suppose \(x(t)\) is an eventually positive solution. Then there exists \(t_{2}\geq t_{1}\) such that \(x(t)>0\) and \(x(t-\lambda)>0\) for \(t\geq t_{2}\). Let

$$ z(t)=a(t) \bigl(x(t)+p(t)x(t-\tau)\bigr)' -\int _{t-\sigma}^{t-\rho}r(s)x(s)\,ds. $$
(4.1)

From (2.1) and (H2) it follows that

$$ z'(t)\leq\bigl(r(t-\sigma)-q(t-\sigma)\bigr)x(t- \sigma)< 0,\quad t\geq t_{2}. $$
(4.2)

So \(z(t)\) is decreasing, and

$$-\infty\leq\lim _{t\rightarrow\infty}z(t)=c< \infty. $$

If \(c=-\infty\), from (4.1) and the boundedness of \(x(t)\) and \(r(t)\), we have

$$\lim _{t\rightarrow\infty}a(t) \bigl(x(t)+p(t)x(t-\tau)\bigr)'=-\infty. $$

Then there exist \(l_{1}>0\) and \(t_{3}\geq t_{2}\) such that

$$\bigl(x(t)+p(t)x(t-\tau)\bigr)'\leq-\frac{l_{1}}{a(t)},\quad t\geq t_{3}. $$

Integrating both sides of the above inequality, according to (H1), we obtain

$$\lim _{t\rightarrow\infty}\bigl(x(t)+p(t)x(t-\tau)\bigr)=-\infty, $$

which contradicts the boundedness of \(x(t)\) and \(p(t)\). This contradiction shows that \(|c|<\infty\), i.e., \(z(t)\) is bounded.

From (4.2) it follows that

$$ x(t-\sigma)\leq\frac{1}{r(t-\sigma)-q(t-\sigma)}z'(t). $$
(4.3)

So \(x\in L^{1}[t_{0},\infty)\) by (H4).

(i) If \(c>0\), from (4.1) we have

$$z(t)\leq a(t) \bigl(x(t)+p(t)x(t-\tau)\bigr)',\quad t \geq t_{2}. $$

Therefore, since \(z(t) \to c\) as \(t \to\infty\),

$$\bigl(x(t)+p(t)x(t-\tau)\bigr)'\geq\frac{c}{a(t)},\quad t \geq t_{2}. $$

From (H1) we have \(\lim_{t\rightarrow\infty}(x(t)+p(t)x(t-\tau))=\infty\), which contradicts the boundedness of \(x(t)\).

(ii) If \(c<0\), in view of \(x\in L^{1}[t_{0},\infty)\), we have

$$\lim _{t\rightarrow\infty}\int_{t-\sigma}^{t-\rho}r(s)x(s)\,ds=0. $$

Then, since \(z(t) \to c\) as \(t \to\infty\), there exist \(\epsilon\in(0, -c)\) and \(t_{4}\geq t_{2}\) such that

$$a(t) \bigl(x(t)+p(t)x(t-\tau)\bigr)'\leq c+\epsilon< 0,\quad t \geq t_{4}. $$

Hence, by (H1) again, we obtain

$$\lim _{t\rightarrow\infty}\bigl(x(t)+p(t)x(t-\tau)\bigr)=-\infty, $$

a contradiction to the boundedness of \(x(t)\) and \(p(t)\).

(iii) If \(c=0\), in view of \(z'(t)<0\), we have \(z(t)>0\). So

$$a(t) \bigl(x(t)+p(t)x(t-\tau)\bigr)'>\int_{t-\sigma}^{t-\rho}r(s)x(s)\,ds>0,\quad t \geq t_{2}. $$

Since \(x(t)+p(t)x(t-\tau)\) is positive and increasing, the integral

$$\int^{\infty}_{t_{0}}\bigl(x(t)+p(t)x(t-\tau)\bigr)\,dt $$

is divergent, a contradiction to \(x\in L^{1}[t_{0},\infty)\). The contradictions obtained in the above three cases show that (2.1) has no bounded eventually positive solution. Now suppose that \(x(t)\) is a bounded eventually negative solution. Then \(x(t-\lambda) <0\) for some \(t_{2}> t_{1}\) and all \(t \geq t_{2}\). From (2.1), (4.1) and (H2), we have

$$ z'(t) \geq\bigl(r(t-\sigma)-q(t-\sigma)\bigr)x(t-\sigma)>0,\quad t \geq t_{2}. $$
(4.4)

So \(z(t)\) is increasing and \(-\infty< \lim_{t \to\infty} z(t)=c \leq \infty\). Then an argument parallel to the above also leads to contradictions. Therefore, every bounded solution of (2.1) is oscillatory. □

Proof of Theorem 2.3

Without loss of generality, suppose that \(x(t)\) is an eventually positive solution. Take \(t_{2} \geq t_{1}\) such that \(x(t-\lambda)>0\) for all \(t \geq t_{2}\). Let

$$ z(t)=a(t) \bigl(x(t)+p(t)x(t-\tau)\bigr)'+ \int _{t-\rho}^{t-\sigma}q(s)x(s)\,ds. $$
(4.5)

From (2.1) it follows that

$$ z'(t)\leq\bigl(r(t-\rho)-q(t-\rho)\bigr)x(t-\rho)< 0,\quad t \geq t_{2}. $$
(4.6)

So \(z(t)\) is decreasing and

$$-\infty\leq\lim _{t\rightarrow\infty}z(t)=c< \infty. $$

If \(c=-\infty\), then

$$\lim_{t\rightarrow\infty}a(t) \bigl(x(t)+p(t)x(t-\tau)\bigr)'=- \infty. $$

By (H1), we obtain \(\lim_{t\rightarrow\infty}(x(t)+p(t)x(t-\tau))=-\infty\), which contradicts \(x(t)+p(t)x(t-\tau)>0\). Therefore \(|c|<\infty\) so \(z(t)\) is bounded.

From (4.6) we have

$$ x(t-\rho)\leq\frac{1}{r(t-\rho)-q(t-\rho)}z'(t),\quad t \geq t_{2} $$
(4.7)

so, by (H4), \(x\in L^{1}[t_{0},\infty)\) and \(\lim_{t\rightarrow\infty} \int^{t-\sigma}_{t-\rho}q(s)x(s)\,ds=0\). Since \(1/a(t)\) is bounded, by (4.5), \((x(t)+p(t)x(t-\tau))'\) is bounded. This implies that \(x(t)+p(t)x(t-\tau)\) is uniformly continuous on \([t_{1},\infty)\). Note that the property \(x\in L^{1}[t_{0},\infty)\) and the boundedness of \(p(t)\) imply that \(x(t)+p(t)x(t-\tau) \in L^{1}[t_{0},\infty)\). Hence \(\lim_{t\rightarrow\infty} (x(t)+p(t)x(t-\tau))=0\), so \(\lim_{t\rightarrow\infty} x(t)=0\). Therefore, every solution x of (2.1) which is not in the class of \(o(1)\) as \(t \to\infty\) is oscillatory. □

Proof of Theorem 2.4

Without loss of generality, assume that \(x(t)\) is a bounded eventually positive solution and \(z(t)\) is defined by (4.1). Take \(t_{2} \geq t_{1}\) such that \(x(t-\lambda)>0\) for \(t \geq t_{2}\). From (2.1) and (H3), we have

$$ z'(t)\geq\bigl(r(t-\sigma)-q(t-\sigma)\bigr)x(t- \sigma)>0,\quad t\geq t_{2}. $$
(4.8)

So \(z(t)\) is increasing. Then

$$-\infty< \lim_{t\rightarrow\infty} z(t)=d\leq\infty. $$

If \(\lim_{t\rightarrow\infty} z(t)=\infty\), then from (4.1) and the boundedness of \(x(t)\) and \(r(t)\), we obtain

$$\lim_{t\rightarrow\infty}a(t) \bigl(x(t)+p(t)x(t-\tau)\bigr)'= \infty. $$

Then there exist \(l_{2}>0\) and \(t_{3}\geq t_{2}\) such that

$$a(t) \bigl(x(t)+p(t)x(t-\tau)\bigr)'\geq l_{2},\quad t\geq t_{3}. $$

From (H1) it follows that

$$\lim _{t\rightarrow\infty}\bigl(x(t)+p(t)x(t-\tau)\bigr)=\infty, $$

a contradiction to the boundedness of \(x(t)\) and \(p(t)\). So \(|d|<\infty\) and \(z(t)\) is bounded. From (4.8) we have

$$x(t-\sigma)\leq\frac{1}{r(t-\sigma)-q(t-\sigma)} z'(t),\quad t \geq t_{2}. $$

Therefore, by (H4), \(x\in L^{1}[t_{0},\infty)\). By the same reasoning as that used in the proof of Theorem 2.3, we have \(\lim_{t \to\infty}x(t)=0\). Therefore, every bounded solution x of (2.1) which is not in the class of \(o(1)\) as \(t \to\infty\) must be oscillatory. □

Proof of Theorem 2.5

Without loss of generality, suppose that \(x(t)\) is a bounded eventually positive solution. Let \(z(t)\) be defined by (4.5). Take \(t_{2} \geq t_{1}\) such that \(x(t-\lambda )>0\) for \(t \geq t_{2}\). From (2.1) and (H3), we have

$$ z'(t)\geq\bigl(r(t-\rho)-q(t-\rho)\bigr)x(t-\rho)>0,\quad t\geq t_{2}. $$
(4.9)

Hence \(z(t)\) is increasing and

$$-\infty< \lim _{t\rightarrow\infty}z(t)=d\leq\infty. $$

By using the method similar to that used in the proof of Theorem 2.4, we have \(-\infty< d<\infty\). Therefore \(z(t)\) is bounded. From (4.9) it follows that

$$x(t-\rho) \leq\frac{1}{r(t-\rho)-q(t-\rho)} z'(t),\quad t \geq t_{2}. $$

Thus, by (H4), \(x\in L^{1}[t_{0},\infty)\) and \(\lim_{t\rightarrow\infty}\int^{t-\sigma}_{t-\rho}q(s)x(s)\,ds=0\). Then it follows from (4.5) that

$$\lim _{t\rightarrow\infty}a(t) \bigl(x(t)+p(t)x(t-\tau)\bigr)'=d. $$

(i) If \(d>0\), then there exists \(t_{5}\geq t_{2}\) such that

$$a(t) \bigl(x(t)+p(t)x(t-\tau)\bigr)'\geq\frac{d}{2},\quad t\geq t_{5}. $$

From (H1) we have

$$\lim_{t\rightarrow\infty}\bigl(x(t)+p(t)x(t-\tau)\bigr)=\infty, $$

which contradicts the boundedness of \(x(t)\) and \(p(t)\).

(ii) If \(d<0\), similar to the case (i), we have

$$\lim_{t\rightarrow\infty}\bigl(x(t)+p(t)x(t-\tau)\bigr)=-\infty, $$

a contradiction to the boundedness of \(x(t)\) and \(p(t)\) again. Hence \(d=0\), i.e., \(\lim_{t\rightarrow\infty} z(t)=0\). On the other hand, from (4.9) and \(\lim_{t\rightarrow\infty}z(t)=0\), we have \(z(t)<0\). In view of (4.5), \((x(t)+p(t)x(t-\tau))'<0\), which implies that \(x(t)+p(t)x(t-\tau)\) is decreasing. From \(x(t)+p(t)x(t-\tau)\in L^{1}[t_{0},\infty)\), we have \(\lim_{t\rightarrow\infty}(x(t)+p(t)x(t-\tau))=0\). Thus \(\lim_{t\rightarrow\infty}x(t)=0\). Therefore, every bounded solution x of (2.1) which is not in the class of \(o(1)\) as \(t \to\infty\) must be oscillatory. □

Proof of Theorem 3.1

Suppose that \(x(t)\) is a bounded non-oscillatory solution. Without loss of generality, we assume that \(x(t)\) is an eventually positive solution. Let

$$ z(t)=a(t) \bigl(x(t)-p(t)x(t-\tau)\bigr)' +\int _{t-\rho}^{t-\sigma}q(s)x(s)\,ds. $$
(4.10)

From a proof similar to that of Theorem 2.4, we obtain

$$z'(t)>0, \lim _{t\rightarrow\infty} z(t)=c, |c|< \infty,\mbox{ and } x\in L^{1}[t_{0},\infty). $$

(i) If \(c>0\), from (4.10) it follows that

$$\lim_{t\rightarrow\infty} a(t) \bigl(x(t)-p(t)x(t-\tau)\bigr)'=c> \frac{c}{2}. $$

So, for large enough t,

$$\bigl(x(t)-p(t)x(t-\tau)\bigr)' \geq\frac{c}{2a(t)}. $$

Hence \(\lim_{t\rightarrow\infty}(x(t)-p(t)x(t-\tau))=\infty\) by (H1), which contradicts the boundedness of \(x(t)\) and \(p(t)\).

(ii) If \(c<0\), in view of \(\lim_{t\rightarrow\infty}z(t)=c\) and \(x\in L^{1}[t_{0},\infty)\), there exists \(t_{6}\geq t_{1}\) such that

$$a(t) \bigl(x(t)-p(t)x(t-\tau)\bigr)' \leq \frac{c}{2}< 0, \quad t \ge t_{6}. $$

Hence \(\lim_{t\rightarrow\infty}(x(t)-p(t)x(t-\tau))=-\infty\) by (H1), a contradiction to the boundedness of \(x(t)\) and \(p(t)\) again.

(iii) If \(c=0\), in view of \(z'(t)>0\), we have \(z(t)<0\). Further,

$$\bigl(x(t)-p(t)x(t-\tau)\bigr)'< 0. $$

We show that \(x(t)-p(t)x(t-\tau)>0\). In fact, if there exists \(t_{7}\geq t_{1}\) such that \(x(t_{7})-p(t_{7})x(t_{7}-\tau)<0\), then, for all \(t \geq t_{7}\),

$$x(t)-p(t)x(t-\tau) \leq x(t_{7})-p(t_{7})x(t_{7}- \tau)< 0. $$

This contradicts \(x(t)-p(t)x(t-\tau)\in L^{1}[t_{0},\infty)\). Hence \(x(t)-p(t)x(t-\tau)>0\) for all large \(t\ge t_{1}\). From this and the assumption on p, we have \(x(t) \ge p(t)x(t-\tau) \ge x(t-\tau)\), which contradicts \(x\in L^{1}[t_{0},\infty)\). Thus (3.1) is bounded oscillatory. □

Proof of Theorem 3.2

Without loss of generality, assume that \(x(t)\) is a bounded eventually positive solution. By a proof similar to that of Theorem 2.4, we obtain \(\lim_{t\rightarrow\infty}(x(t)-p(t)x(t-\tau))=0\). Suppose

$$\limsup_{t\rightarrow\infty} x(t)=l>0. $$

So there exists a sequence \(\{t_{k}\}\) such that \(t_{k} \rightarrow \infty\) as \(k \rightarrow\infty\) and

$$\lim_{k\rightarrow\infty} x(t_{k})=l>0. $$

(i) If \(0\le p(t)\le p_{1}<1\), then we have \((1-p_{1})l \le 0\), which contradicts \(l>0\) and \(1-p_{1}>0\).

(ii) If \(1< p_{2}\le p(t)\), then we have \(0\le(1-p_{2})l\), which contradicts \(l>0\) and \(p_{2}-1>0\). Therefore, we must have

$$\limsup _{t\rightarrow\infty}x(t)=0. $$

Then \(\lim_{t\rightarrow\infty} x(t)=0\) as \(x(t)\) is eventually positive. This shows that (3.1) is bounded almost oscillatory. □

Proof of Theorem 3.3

Without loss of generality, suppose that \(x(t)\) is a bounded eventually positive solution. As in the proof of Theorem 2.3, we obtain

$$\lim_{t\rightarrow\infty}\bigl(x(t)-p(t)x(t-\tau)\bigr)=0. $$

Then the rest follows from the proof of Theorem 3.2. □

Proof of Theorem 3.4

Without loss of generality, suppose that \(x(t)\) is a bounded eventually positive solution. Let

$$ z(t)=a(t) \bigl(x(t)-p(t)x(t-\tau)\bigr)'- \int _{t-\sigma}^{t-\rho}r(s)x(s)\,ds. $$
(4.11)

By the reasoning similar to that used in the proof of Theorem 2.1, we have \(x\in L^{1}[t_{0},\infty)\), \(\lim_{t\rightarrow\infty}z(t)=c=0\) and \(z'(t)<0\). So \(z(t)>0\), \((x(t)-p(t)x(t-\tau))'>0\) and \(x(t)-p(t)x(t-\tau)\) is increasing. We claim that \(x(t)-p(t)x(t-\tau)<0\) for \(t \geq t_{1}\). In fact, if there exists \(t_{8}\geq t_{1}\) such that \(x(t_{8})-p(t_{8})x(t_{8}-\tau) \geq0\), then \(x(t)-p(t)x(t-\tau) \geq x(t_{8}+1)-p(t_{8}+1)x(t_{8}+1-\tau)>0\) for \(t \geq t_{8}+1 \), which contradicts \(x(t)-p(t)x(t-\tau)\in L^{1}[t_{1},\infty)\). Hence \(x(t)-p(t)x(t-\tau)<0\) for all \(t\ge t_{1}\). If \(0\le p(t)\le p<1\) is satisfied, then \(x(t)< px(t-\tau)\) for all \(t\ge t_{1}\). This implies that \(\lim_{t\rightarrow\infty}x(t)=0\).

If \(1/a(t)\) is bounded and \(1< p_{2}\le p(t)\), from the proof of Theorem 3.2, we have \(\lim_{t \to\infty}(x(t)-p(t)x(t-\tau))=0\) and thus \(\lim_{t\rightarrow\infty}x(t)=0\). Therefore, (3.1) is bounded almost oscillatory. □