Some dynamic integral inequalities with mixed nonlinearities on time scales

The objective of this paper is to study some dynamic integral inequalities on time scales, which provide explicit bounds on unknown functions. Our results include many known ones in the literature and can be used as tools in the study of qualitative theory of certain classes of dynamic equations with mixed nonlinearities on time scales.

The theory of time scales was introduced and developed by Hilger [1] and Bohner and Peterson [2, 3] in order to unify continuous and discrete analysis. It has been applied to various fields of mathematics. In particular, many authors have extended some integral inequalities used in the theory of differential, difference, and integral equations to an arbitrary time scale; see, for instance, the papers [4–16] and the references cited therein.

In what follows, let us briefly comment on a number of closely related results which motivated our study. Li and Sheng [8] established several integral inequalities and studied the boundedness properties of some nonlinear dynamic equations, one of which we present below for convenience of the reader. In what follows, we use the following notation (some other concepts related to the notion of time scales; see Bohner and Peterson [2]):

ℝ denotes the set of real numbers, \(\mathbb{R}_{+}=[0,\infty)\), \(\mathbb{T}\) is an arbitrary time scale, and the set \(\mathbb{T}^{k}\) is derived from \(\mathbb{T}\) as follows: if \(\mathbb{T}\) has a left-scattered maximum \(m_{0}\), then \(\mathbb{T}^{k}=\mathbb{T}-\{m_{0}\}\), otherwise \(\mathbb{T}^{k}=\mathbb{T}\).

Theorem 1.1

[8, Theorem 3.2]

Assume that \(u,a,b,f,g:\mathbb{T}^{k}\rightarrow\mathbb{R}_{+}\) are rd-continuous functions and let p and q be real constants satisfying \(p\geq q>0\). Then the inequality

implies that, for any \(K>0\),

where \(t\in\mathbb{T}^{k}\) and \(A(t)=b(t)(f(t)+qK^{(q-p)/p}g(t)/p)\).

Sun and Hassan [15] studied the following dynamic integral inequality with mixed nonlinearities.

Theorem 1.2

[15, Theorem 1]

Assume that \(u,a,b,g,h_{1},h_{2}:\mathbb{T}^{k}\rightarrow \mathbb{R}_{+}\) are rd-continuous functions and let \(\lambda_{1}\) and \(\lambda_{2}\) be real constants satisfying \(0<\lambda_{1}<1<\lambda_{2}\). Then, for any rd-continuous functions \(k_{1}(t)>0\) and \(k_{2}(t)\geq0\) on \(\mathbb{T}^{k}\) satisfying \(k(t)=k_{1}(t)-k_{2}(t)\geq0\) and \(\mu(t)k(t)b(\sigma(t))<1\) for \(t\in\mathbb{T}^{k}\), the inequality

implies that

where

and

The aim of this paper is to further generalize some integral inequalities on time scales that have been reported in [7, 8, 15]. We consider the following dynamic integral inequalities with mixed nonlinearities

and

where \(p\geq q>0\), \(p\geq r>0\), \(0<\lambda_{1}<p<\lambda_{2}\), p, q, r, \(\lambda_{1}\), and \(\lambda_{2}\) are real constants, \(u,a,b,f,g,h_{1},h_{2},l,m:\mathbb{T}^{k}\rightarrow\mathbb{R}_{+}\) are rd-continuous functions, and \(w:\mathbb{T}\times \mathbb{T}^{k}\rightarrow\mathbb{R}\) is a continuous function.

In what follows, ℤ denotes the set of integers, \(\mathbb{N}_{0}\) denotes the set of nonnegative integers, \(\mathrm{C}_{\mathrm{rd}}\) denotes the set of rd-continuous functions. We say that a function \(p: \mathbb{T}\rightarrow\mathbb{R}\) is regressive provided \(1+\mu(t)p(t)\neq0\), for all \(t\in\mathbb{T}^{k}\). The set of all regressive and rd-continuous functions will be denoted in this paper by ℛ, and \(\mathcal{R}^{+}=\{p\in \mathcal{R}:1+\mu(t)p(t)>0, \mbox{for all } t\in\mathbb{T}\}\).

The following lemmas are very useful in the proof of our main results.

Lemma 2.1

[2, Theorem 6.1]

Let \(u, b\in\mathrm{C}_{\mathrm{rd}} \) and \(a\in\mathcal{R}^{+}\). Then

yields

Lemma 2.2

[2, Theorem 1.117]

Let \(t_{0}\in\mathbb {T}^{k}\) and \(w:\mathbb{T}\times\mathbb{T}^{k}\rightarrow\mathbb{R}\) be continuous at \((t,t)\), \(t\in\mathbb{T}^{k}\) with \(t>t_{0}\). Assume that \(w^{\Delta}(t,\cdot)\) is rd-continuous on \([t_{0},\sigma(t)]\). Suppose that, for each \(\varepsilon>0\), there exists a neighborhood \({\mathcal{U}}\) of t, independent of \(\tau\in[t_{0},\sigma(t)]\), such that

where \(w^{\Delta}\) denotes the derivative of w with respect to the first variable. Then

implies that

Lemma 2.3

[5, Lemma 2.1]

Assume that \(a\geq0\) and \(p\geq q>0\). Then

for any \(K>0\).

Lemma 2.4

Let u be a nonnegative function, \(0<\lambda_{1}<p<\lambda_{2}, c_{1}\geq0, c_{2}> 0\), \(k_{1}>0\), and \(k_{2}\geq0\). Then, for \(i=1,2\),

where

Proof

Set \(F_{i}(u)=(-1)^{i+1}c_{i}u^{\lambda _{i}}+(-1)^{i}k_{i}u^{p}\). It is not difficult to verify that \(F_{i}\) obtains its maximum at \(u=({\lambda_{i}c_{i}}/{(k_{i}p}))^{{1}/{(p-\lambda_{i})}}\) and

The proof is complete. □

Theorem 2.1

Assume that \(u,a,b,f,g,h_{1},h_{2},l,m:\mathbb{T}^{k}\rightarrow\mathbb{R}_{+}\) are rd-continuous functions. Then, for any rd-continuous functions \(k_{1}(t)>0\) and \(k_{2}(t)\geq0\) on \(\mathbb{T}^{k}\) satisfying \(k(t)=k_{1}(t)-k_{2}(t)\geq0\) and \(\mu(t)k(t)b(\sigma(t))<1\) for \(t\in\mathbb{T}^{k}\), the inequality (I) implies that

where

and

Proof

Define a function y by

Then \(y(t_{0})=0\) and

On the basis of a straightforward computation and Lemma 2.4, we have

By virtue of Lemma 2.3, for any \(K > 0\), we obtain

Using inequalities (2.2)-(2.4), we conclude that

which implies that

that is,

where \(D(t)=[1+\mu(t)B(t)]C(t)\). Note that \(y,D\in\mathrm{C}_{\mathrm{rd}}\) and \(A\oplus B\in\Re^{+}\). By Lemma 2.1, we get the desired inequality (2.1). This completes the proof. □

Remark 2.1

If \(p=1\) and \(g(t)=m(t)=l(t)=0\), then (2.1) reduces to the inequality established in Theorem 1.2.

Remark 2.2

If \(m(t)=0\), \(l(t)=0\), and \(h_{i}(t)=0\) (\(i=1,2\)), then Theorem 2.1 reduces to Theorem 1.1.

Remark 2.3

Theorem 2.1 can be applied on an arbitrary time scale. Thus, we immediately obtain the following corollaries for some peculiar time scales.

Corollary 2.1

Let \(\mathbb{T}=\mathbb{R}\) and assume that \(u,a,b,f,g,h_{1},h_{2},l,m:[t_{0},\infty)\rightarrow\mathbb{R}_{+}\) are continuous. Then, for any continuous functions \(k_{1}(t)>0\) and \(k_{2}(t)\geq0\) satisfying \(k(t)=k_{1}(t)-k_{2}(t)\geq0\) on \([t_{0},\infty)\), the inequality (I) yields

where

and

Corollary 2.2

Let \(\mathbb{T}=\mathbb{Z}\) and \(u,a,b,f,g,h_{1},h_{2},l,m:\mathbb{N}_{0}\rightarrow \mathbb{R}_{+}\). Then, for any functions \(k_{1}(t)>0\) and \(k_{2}(t)\geq0\) satisfying \(k(t)=k_{1}(t)-k_{2}(t)\geq0\) and \(k(t)b(t+1)<1\) on \(\mathbb{N}_{0}\), the inequality (I) implies that

where

and

Theorem 2.2

Assume that \(u,a,b,f,g,h_{1},h_{2},l,m:\mathbb{T}^{k}\rightarrow\mathbb{R}_{+}\) are rd-continuous functions, \(w(t,s)\) is defined as in Lemma 2.2 such that \(w(\sigma(t),t)\geq0\) and \(w^{\Delta}(t,s)\geq0\) for \(t,s\in\mathbb{T}\) with \(s\leq t\). Then, for any rd-continuous functions \(k_{1}(t)>0\) and \(k_{2}(t)\geq0\) on \(\mathbb{T}^{k}\) satisfying \(k(t)=k_{1}(t)-k_{2}(t)\geq0\) and \(\mu(t)\hat{B}(t)<1\) for \(t\in\mathbb{T}^{k}\) with

the inequality (II) implies that

where

A and C are defined as in Theorem 2.1.

Proof

Define a new function z by

Then \(z(t_{0})=0\) and

Using Lemmas 2.2-2.4 and combining (2.6) and (2.7), we deduce that

Similar to the proof of Theorem 2.1, we obtain (2.5). The proof is complete. □

Remark 2.4

The inequality established in Theorem 2.2 generalizes that reported in [7, Theorem 3.2].

On the basis of Theorem 2.2, the following two corollaries are easily obtained.

Corollary 2.3

Let \(\mathbb{T}=\mathbb{R}\) and assume that \(u,a,b,f,g,h_{1},h_{2},l,m:[t_{0},\infty)\rightarrow\mathbb{R}_{+}\) are continuous. Suppose further that \(w(t,s)\) and its partial derivative \(\partial w(t,s)/\partial t\) are real-valued nonnegative continuous functions for \(t,s\in[t_{0},\infty)\) with \(s\leq t\). Then, for any continuous functions \(k_{1}(t)>0\) and \(k_{2}(t)\geq0\) on \([t_{0},\infty)\) satisfying \(k(t)=k_{1}(t)-k_{2}(t)\geq0\), the inequality (II) implies that

where

\(A_{1}\) and \(C_{1}\) are the same as in Corollary 2.1.

Corollary 2.4

Let \(\mathbb{T}=\mathbb{Z}\) and \(u,a,b,f,g,h_{1},h_{2},l,m:\mathbb{N}_{0}\rightarrow \mathbb{R}_{+}\). Assume that \(w(t,s)\) and \(\Delta_{1}w(t,s)\) are real-valued nonnegative functions for \(t,s \in\mathbb{N}_{0}\) with \(s\leq t\). Then, for any functions \(k_{1}(t)>0\) and \(k_{2}(t)\geq0\) satisfying \(k(t)=k_{1}(t)-k_{2}(t)\geq0\) and \(\hat{B}_{2}(t)<1\) on \(\mathbb{N}_{0}\) with

the inequality (II) yields

where \(\Delta_{1}w(t,s)=w(t+1,s)-w(t,s)\) for \(t,s\in\mathbb{N}_{0}\) with \(s\leq t\),

\(A_{2}\) and \(C_{2}\) are defined as in Corollary 2.2.

Remark 2.5

By choosing possible values of \(k_{1}\) and \(k_{2}\), one can derive many explicit estimates for dynamic integral inequalities of types (I) and (II). For instance, if we let \(k_{1}=k_{2}>0\), then \(B(t)=\tilde{B}(t)=0\). In this case, Theorems 2.1 and 2.2 take simpler forms.

The following example illustrates possible applications of our main results.

Example 3.1

Consider the following dynamic equation

where \(C_{0}\) is a real constant, \(F, U:\mathbb{T}^{k}\times \mathbb{R}\times\mathbb{R}\rightarrow\mathbb{R}\), \(H:\mathbb{T}^{k}\times\mathbb{R}\rightarrow\mathbb{R}\) are continuous functions. Assume that, for \(t\in\mathbb{T}^{k}\),

where \(p\geq q>0\), \(p\geq r>0\), \(0<\lambda_{1}<p<\lambda_{2}\), p, q, r, \(\lambda_{1}\), and \(\lambda_{2}\) are real constants, f, g, \(h_{1}\), \(h_{2}\), and m are nonnegative rd-continuous functions on \(\mathbb{T}^{k}\). Then every solution u of (3.1) satisfies, for any \(K>0\),

where

and

where \(k_{1}(t)>0\) and \(k_{2}(t)\geq0\) are any rd-continuous functions satisfying \(k(t)=k_{1}(t)-k_{2}(t)=0\) for \(t\in \mathbb{T}^{k}\).

As a matter of fact, the solution u of (3.1) satisfies the following equivalent equation

It follows now from (3.2) and (3.4) that

Using Theorem 2.1 in (3.5), we conclude that (3.3) is satisfied.

This research was supported by the NNSF of China (Grant Nos. 11171178 and 11271225) and the NSF of Shandong Province (ZR2012AL03).

Authors and Affiliations

1. School of Electronic and Information Engineering, Xi’an Jiaotong University, Xi’an, Shaanxi, 710049, P.R. China

   Yazhou Tian & Yuanli Cai

2. Qingdao Technological University, Feixian, Shandong, 273400, P.R. China

   Yazhou Tian & Tongxing Li

3. School of Science, Jiangnan University, Wuxi, Jiangsu, 214122, P.R. China

   Lianzhong Li

Corresponding author

Correspondence to Tongxing Li.

Competing interests

The authors declare that they have no competing interests.

Authors’ contributions

All four authors contributed equally to this work. They all read and approved the final version of the manuscript.

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