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Hindawi Publishing Corporation Advances in Difference Equations Volume 2010, Article ID 584375, 13 pages doi:10.1155/2010/584375 ResearchArticleExistenceofPeriodicSolutionsforp-LaplacianEquationsonTime Scales Fengjuan Cao, 1 Zhenlai Han, 1, 2 and Shurong Sun 1, 3 1 School of Science, University of Jinan, Jinan, Shandong 250022, China 2 School of Control Science and Engineering, Shandong University, Jinan, Shandong 250061, China 3 Department of Mathematics and Statistics, Missouri U niversity of Science and Technology, Rolla, MO 65409-0020, USA Correspondence should be addressed to Zhenlai Han, hanzhenlai@163.com Received 30 July 2009; Revised 15 October 2009; Accepted 18 November 2009 Academic Editor: A. Pankov Copyright q 2010 Fengjuan Cao et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. We systematically explore the periodicity of Li ´ enard type p-Laplacianequationsontime scales. Sufficient criteria are established for the existenceofperiodicsolutionsfor such equations, which generalize many known results for differential equations when the time scale is chosen as the set of the real numbers. The main method is based on the Mawhin’s continuation theorem. 1. Introduction In the past decades, periodic problems involving the scalar p-Laplacian were studied by many authors, especially for the second-order and three-order p-Laplacian differential equation, see 1–8 and the references therein. Of the aforementioned works, Lu in 1 investigated the existenceofperiodicsolutionsfor a p-Laplacian Li ´ enard differential equation with a deviating argument ϕ p y t f y t y t h y t g y t − τ t e t , 1.1 by Mawhin’s continuation theorem of coincidence degree theory 3. The author obtained a new result for the existenceofperiodicsolutions and investigated the relation between the existenceofperiodicsolutions and the deviating argument τt. Cheung and Ren 4 studied 2 Advances in Difference Equations the existenceof T-periodic solutionsfor a p-Laplacian Li ´ enard equation with a deviating argument ϕ p x t f x t x t g x t − τ t e t , 1.2 by Mawhin’s continuation theorem. Two results for the existenceofperiodicsolutions were obtained. Such equations are derived from many fields, such as fluid mechanics and elastic mechanics. The theory oftime scales has recently received a lot of attention since it has a tremendous potential for applications. For example, it can be used to describe the behavior of populations with hibernation periods. The theory oftime scales was initiated by Hilger 9 in his Ph.D. thesis in 1990 in order to unify continuous and discrete analysis. By choosing the time scale to be the set of real numbers, the result on dynamic equations yields a result concerning a corresponding ordinary differential equation, while choosing the time scale as the set of integers, the same result leads to a result for a corresponding difference equation. Later, Bohner and Peterson systematically explore the theory oftime scales and obtain many perfect results in 10 and 11. Many examples are considered by the authors in these books. But the researchofperiodicsolutionsontime scales has not got much attention, see 12–16. The methods usually used to explore the existenceofperiodicsolutionsontime scales are many fixed point theory, upper and lower solutions, Masseras theorem, and so on. For example, K aufmann and Raffoul in 12 use a fixed point theorem due to Krasnosel’ski to show that the nonlinear neutral dynamic system with delay x Δ t −a t x σ t c t x Δ t − k q t, x t ,x t − k ,t∈ T, 1.3 has a periodic solution. Using the contraction mapping principle the authors show that the periodic solution is unique under a slightly more stringent inequality. The Mawhin’s continuation theorem has been extensively applied to explore the existence problem in ordinary di fferential difference equations but rarely applied to dynamic equationson general time scales. In 13, Bohner et al. introduce the Mawhin’s continuation theorem to explore the existenceofperiodicsolutions in predator-prey and competition dynamic systems, where the authors established some suitable sufficient criteria by defining some operators ontime scales. In 14, Li and Zhang have studied the periodicsolutionsfor a periodic mutualism model x Δ t r 1 t k 1 t α 1 t exp y t − τ 2 t, y t 1 exp y t − τ 2 t, y t − exp { x t − σ 1 t, x t } , y Δ t r 2 t k 2 t α 2 t exp x t − τ 1 t, y t 1 exp { x t − τ 1 t, x t } − exp y t − σ 2 t, y t 1.4 on a time scale T by employing Mawhin’s continuation theorem, and have obtained three sufficient criteria. Advances in Difference Equations 3 Combining Brouwer’s fixed point theorem with Horn’s fixed point theorem, two classes of one-order linear dynamic equationsontime scales x Δ t a t x t h t , x Δ t f t, x , with the initial condition x t 0 x 0 , 1.5 are considered in 15 by Liu and Li. The authors presented some interesting properties of the exponential function ontime scales and obtain a sufficient and necessary condition that guarantees the existenceof the periodicsolutionsof the equation x Δ tatxtht. In 16, Bohner et al. consider the system x Δ t G t, exp x g 1 t , exp x g 2 t , ,exp x g n t , t −∞ c t, s exp { x s } Δs , 1.6 easily verifiable sufficient criteria are established for the existenceofperiodicsolutionsof this class of nonautonomous scalar dynamic equationsontime scales, the approach that authors used in this paper is based on Mawhin’s continuation theorem. In this paper, we consider the existenceofperiodicsolutionsforp-Laplacianequationson a time scales T ϕ p x Δ t Δ f x t x Δ t g x t e t ,t∈ T, 1.7 where p>2 is a constant, ϕ p s|s| p−2 s, f, g ∈ CR, R,e ∈ CT,R, and e is a function with periodic ω>0. T is a periodictime scale which has the subspace topology inherited from the standard topology on R. Sufficient criteria are established for the existenceofperiodicsolutionsfor such equations, which generalize many known results for differential equations when the time scales are chosen as the set of the real numbers. T he main method is based on the Mawhin’s continuation theorem. If T R, 1.7 reduces to the differential equation ϕ p x t f x t x t g x t e t . 1.8 We will use Mawhin’s continuation theorem to study 1.7. 2. Preliminaries In this section, we briefly give some basic definitions and lemmas ontime scales which are used in what follows. Let T be a time scale a nonempty closed subset of R. The forward and backward jump operators σ,ρ : T → T and the graininess μ : T → R are defined, respectively, by σ t inf { s ∈ T : s>t } ,ρ t sup { s ∈ T : s<t } ,μ t σ t − t. 2.1 4 Advances in Difference Equations We say that a point t ∈ T is left-dense if t>inf T and ρtt. If t < sup T and σtt, then t is called right-dense. A point t ∈ T is called left-scattered if ρt <t,while right-scattered if σt >t.If T has a left-scattered maximum m, then we set T k T \{m}, otherwise set T k T. If T has a right-scattered minimum m, then set T k T \{m}, otherwise set T k T. A function f : T → R is right-dense continuous rd-continuous provided that it is continuous at right-dense point in T and its left side limits exist at left-dense points in T. If f is continuous at each right-dense point and each left-dense point, then f is said to be continuous function on T. Definition 2.1 see 10. Assume f : T → R is a function and let t ∈ T k . We define f Δ t to be the number if it exists with the property that for a given ε>0, there exists a neighborhood U of t such that f σ t − f s − f Δ t σ t − s <ε | σ t − s | , for all s ∈ U. 2.2 We call f Δ t the delta derivative of f at t. If f is continuous, then f is right-dense continuous, and if f is delta differentiable at t, then f is continuous at t. Let f be right-dense continuous. If F Δ tft, for all t ∈ T, then we define the delta integral by t a f s Δs F t − F a , for t, a ∈ T. 2.3 Definition 2.2 see 12. We say that a time scale T is periodic if there is p>0 such that if t ∈ T, then t ± p ∈ T. For T / R, the smallest positive p is called the period of the time scale. Definition 2.3 see 12.LetT / R be a periodictime scale with period p. We say that the function f : T → R is periodic with period ω if there exists a natural number n such that ω np, ft ωft for all t ∈ T, and ω is the smallest number such that f t ωft. If T R, we say that f is periodic with period ω>0ifω is the smallest positive number such that ft ωft for all t ∈ T. Lemma 2.4 see 10. If a, b ∈ T,α,β∈ R, and f, g ∈ CT,R, then A1 b a αftβgtΔt α b a ftΔt β b a gtΔt; A2 if ft ≥ 0 for all a ≤ t<b,then b a ftΔt ≥ 0; A3 if |ft|≤gt on a, b : {t ∈ T : a ≤ t<b}, then | b a ftΔt|≤ b a gtΔt. Advances in Difference Equations 5 Lemma 2.5 H¨older’s inequality 11. Let a, b ∈ T. For rd-continuous functions f, g : a, b → R, one has b a f t g t Δt ≤ b a f t p Δt 1/p b a g t q Δt 1/q , 2.4 where p>1 and q p/p − 1. For convenience, we denote κ min { 0, ∞ ∩ T } ,I ω κ, κ ω ∩ T, g 1 ω I ω g s Δs 1 ω κω κ g s Δs, 2.5 where g ∈ CT,R is an ω-periodic real function, that is, gt ωgt for all t ∈ T. Next, let us recall the continuation theorem in coincidence degree theory. To do so, we introduce the following notations. Let X, Y be real Banach spaces, L :DomL ⊂ X → Y a linear mapping, N : X → Y a continuous mapping. The mapping L will be called a Fredholm mapping of index zero if dimKer L codimIm L<∞ and Im L is closed in Y. If L is a Fredholm mapping of index zero and there exist continuous projections P : X → X, Q : Y → Y such that Im P Ker L, Im L Ker Q ImI −Q, then it follows that L| Dom L∩Ker P : I −PX → Im L is invertible. We denote the inverse of that map by K P . If Ω is an open bounded subset of X, the mapping N will be called L-compact on Ω if QNΩ is bounded and K P I − QN : Ω → X is compact. Since Im Q is isomorphic to Ker L, there exists an isomorphism J :ImQ → Ker L. Lemma 2.6 continuation theorem. Suppose that X and Y are two Banach spaces, and L : Dom L ⊂ X → Y is a Fredholm operator of index 0. Furthermore, let Ω ⊂ X be an open bounded set and N : Ω → Y L-compact on Ω. If B1 Lx / λNx, for all x ∈ ∂Ω ∩ Dom L, λ ∈ 0, 1, B2 Nx / ∈ Im L, for all x ∈ ∂Ω ∩ Ker L, B3 deg{JQN,Ω ∩ Ker L, 0} / 0, where J :ImQ → Ker L is an isomorphism, then the equation Lx Nx has at least one solution in Ω ∩ Dom L. Lemma 2.7 see 13. Let t 1 ,t 2 ∈ I ω and t ∈ T. If g : T → R is ω-periodic, then g t ≤ g t 1 κω κ g Δ s Δs, g t ≥ g t 2 − κω κ g Δ s Δs. 2.6 In order to use Mawhin’s continuation theorem to study the existenceof ω-periodic solutionsfor 1.7, we consider the following system: x Δ 1 t ϕ q x 2 t | x 2 t | q−2 x 2 t , x Δ 2 t −f x 1 t ϕ q x 2 t − g x 1 t e t , 2.7 6 Advances in Difference Equations where 1 <q<2 is a constant with 1/p 1/q 1. Clearly, if xtx 1 t,x 2 t is an ω- periodic solution to 2.7, then x 1 t must be an ω-periodic solution to 1.7. Thus, in order to prove that 1.7 has an ω-periodic solution, it suffices to show that 2.7 has an ω-periodic solution. Now, we set Ψ ω {u, v ∈ CT,R 2 : ut ωut,vt ωvt, for all t ∈ T} with the norm u, v max t∈I ω |ut| max t∈I ω |vt|, for u, v ∈ Ψ ω . It is easy to show that Ψ ω is a Banach space when it is endowed with the above norm ·. Let Ψ ω 0 { u, v ∈ Ψ ω : u 0, v 0 } , Ψ ω c u, v ∈ Ψ ω : u t ,v t ≡ h 1 ,h 2 ∈ R 2 , for t ∈ T . 2.8 Then it is easy to show that Ψ ω 0 and Ψ ω c are both closed linear subspaces of Ψ ω . We claim that Ψ ω Ψ ω 0 ⊕Ψ ω c , and dimΨ ω c 2. Since for any u, v ∈ Ψ ω 0 ∩Ψ ω c , we have ut,vt h 1 ,h 2 ∈ R 2 , and u 1 ω κω κ u s Δs h 1 0, v 1 ω κω κ v s Δs h 2 0, 2.9 so we obtain u, vh 1 ,h 2 0, 0. Take X Y Ψ ω . Define L :DomL x x 1 ,x 2 ∈ C 1 T,R 2 : x t ω x t ,x Δ t ω x Δ t ⊂ X → Y, 2.10 by Lx t x Δ t x Δ 1 t x Δ 2 t , 2.11 and N : X → Y, by Nx t ϕ q x 2 t −f x 1 t ϕ q x 2 t − g x 1 t e t . 2.12 Define the operator P : X → X and Q : Y → Y by Px P x 1 x 2 x 1 x 2 ,Qy Q y 1 y 2 y 1 y 2 ,x∈ X, y ∈ Y. 2.13 It is easy to see that 2.7 can be converted to the abstract equation Lx Nx. Advances in Difference Equations 7 Then Ker L Ψ ω c , Im L Ψ ω 0 , and dimKer L 2 codim Im L. Since Ψ ω 0 is closed in Ψ ω , it follows that L is a Fredholm mapping of index zero. It is not difficult to show that P and Q are continuous projections such that Im P Ker L and Im L Ker Q ImI − Q. Furthermore, the generalized inverse to L P K P :ImL → Ker P ∩ Dom L exists and is given by K P x 1 x 2 ⎛ ⎝ X 1 − X 1 X 2 − X 2 ⎞ ⎠ , where X i t t κ x i s Δs, i 1, 2. 2.14 Since for every x ∈ Ker P ∩ Dom L, we have K P Lx t K P x Δ 1 t x Δ 2 t ⎛ ⎜ ⎜ ⎜ ⎜ ⎜ ⎝ t κ x Δ 1 s Δs − 1 ω κω κ t κ x Δ 1 s ΔsΔt t κ x Δ 2 s Δs − 1 ω κω κ t κ x Δ 2 s ΔsΔt ⎞ ⎟ ⎟ ⎟ ⎟ ⎟ ⎠ ⎛ ⎜ ⎜ ⎜ ⎜ ⎜ ⎝ x 1 t − x 1 κ − 1 ω κω κ x 1 t − x 1 κ Δt x 2 t − x 2 κ − 1 ω κω κ x 2 t − x 2 κ Δt ⎞ ⎟ ⎟ ⎟ ⎟ ⎟ ⎠ ⎛ ⎜ ⎜ ⎜ ⎜ ⎜ ⎝ x 1 t − 1 ω κω κ x 1 t Δt x 2 t − 1 ω κω κ x 2 t Δt ⎞ ⎟ ⎟ ⎟ ⎟ ⎟ ⎠ , 2.15 from the definition of P and the condition that x ∈ Ker P ∩ Dom L, then 1/ω κω κ x 1 tΔt 1/ω κω κ x 2 tΔt 0. Thus, we get K P Lxtxt. Similarly, we can prove that LK P xt xt, for every xt ∈ Im L. So the operator K P is well defined. Thus, QN x 1 x 2 ⎛ ⎜ ⎜ ⎝ 1 ω κω κ ϕ q x 2 s Δs 1 ω κω κ −f x 1 s ϕ q x 2 s − g x 1 s e s Δs ⎞ ⎟ ⎟ ⎠ . 2.16 8 Advances in Difference Equations Denote Nx 1 N 1 ,Nx 2 N 2 . We have K P I − Q N x 1 x 2 ⎛ ⎜ ⎜ ⎜ ⎜ ⎜ ⎝ t κ N 1 s − 1 ω κω κ N 1 r Δr Δs − 1 ω κω κ t κ N 1 s − 1 ω κω κ N 1 r Δr ΔsΔt t κ N 2 s − 1 ω κω κ N 2 r Δr Δs − 1 ω κω κ t κ N 2 s − 1 ω κω κ N 2 r Δr ΔsΔt ⎞ ⎟ ⎟ ⎟ ⎟ ⎟ ⎠ . 2.17 Clearly, QN and K P I − QN are continuous. Since X is a Banach space, it is easy to show that K P I − QNΩ is a compact for any open bounded set Ω ⊂ X. Moreover, QNΩ is bounded. Thus, N is L-compact on Ω. 3. Main Results In this section, we present our main results. Theorem 3.1. Suppose that there exist positive constants d 1 and d 2 such that the following conditions hold: i uσtu Δ tfut < 0, |uσt| >d 1 ,t∈ T, ii uσtgut − et < 0, |uσt| >d 2 ,t∈ T, then 1.7 has at least one ω-periodic solution. Proof. Consider the equation Lx λNx, λ ∈ 0, 1, where L and N are defined by the second section. Let Ω 1 {x ∈ X : Lx λNx, λ ∈ 0, 1}. If x x 1 t x 2 t ∈ Ω 1 , then we have x Δ 1 t λϕ q x 2 t , x Δ 2 t −f x 1 t x Δ 1 t − λg x 1 t λe t . 3.1 From the first equation of 3.1,weobtainx 2 tϕ p 1/λx Δ 1 t, and then by substituting it into the second equation of 3.1,weget ϕ p 1 λ x Δ 1 t Δ −f x 1 t x Δ 1 t − λg x 1 t λe t . 3.2 Advances in Difference Equations 9 Integrating both sides of 3.2 from κ to κ ω, noting that x 1 κx 1 κ ω,x Δ 1 κ x Δ 1 κ ω, and applying Lemma 2.4, we have κω κ f x 1 t x Δ 1 t Δt − κω κ g x 1 t − e t Δt, 3.3 that is, κω κ f x 1 t x Δ 1 t g x 1 t − e t Δt 0. 3.4 There must exist ξ ∈ I ω such that f x 1 ξ x Δ 1 ξ g x 1 ξ − e ξ ≥ 0. 3.5 From conditions i and ii, when xσξ > max{d 1 ,d 2 }, we have fx 1 ξx Δ 1 ξ < 0, and gx 1 ξ − eξ < 0, which contradicts to 3.5. Consequently xσξ ≤ max{d 1 ,d 2 }. Similarly, there must exist η ∈ I ω such that f x 1 η x Δ 1 η g x 1 η − e η ≤ 0. 3.6 Then we have xση ≥−max{d 1 ,d 2 }. Applying Lemma 2.7,weget − max { d 1 ,d 2 } − κω κ x Δ 1 s Δs ≤ x 1 t ≤ max { d 1 ,d 2 } κω κ x Δ 1 s Δs. 3.7 Let d max{d 1 ,d 2 }. Then 3.7 equals to the following inequality: | x 1 t | ≤ d κω κ x Δ 1 s Δs. 3.8 Let E 1 {t ∈ I ω : |x 1 t|≤d},E 2 {t ∈ I ω : |x 1 t| >d}. 10 Advances in Difference Equations Consider the second equation of 3.1 and 3.8, then we have κω κ x Δ 1 t x 2 t Δt − κω κ x 1 σ t x Δ 2 t Δt κω κ f x 1 t x Δ 1 t x 1 σ t Δt λ κω κ x 1 σ t g x 1 t − e t Δt ≤ κω κ f x 1 t x Δ 1 t | x 1 σ t | Δt λ E 1 x 1 σ t g x 1 t − e t Δt λ E 2 x 1 σ t g x 1 t − e t Δt ≤ sup t∈I ω f x 1 t d κω κ x Δ 1 t Δt κω κ x Δ 1 t Δt λ E 1 x 1 σ t g x 1 t − e t Δt ≤ sup t∈I ω f x 1 t κω κ x Δ 1 t Δt 2 d sup t∈I ω f x 1 t κω κ x Δ 1 t Δt λ E 1 x 1 σ t g x 1 t − e t Δt. . 3.9 Applying Lemma 2.5,weobtainthat 1 λ p−1 κω κ x Δ 1 t p Δt ≤ ω sup t∈I ω f x 1 t κω κ x Δ 1 t 2 Δt d sup t∈I ω f x 1 t κω κ x Δ 1 t Δt λ d κω κ x Δ 1 t Δt κω κ g x 1 t − e t Δt ≤ Q 1 κω κ x Δ 1 t 2 Δt Q 2 κω κ x Δ 1 t Δt λdω sup t∈I ω g x 1 t − e t ≤ Q 1 κω κ x Δ 1 t 2 Δt Q 2 κω κ x Δ 1 t Δt Q 3 , . 3.10 [...]... 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Δ0 , 0} / 0, 3.25 so the condition (B3) of Lemma 2.6 is satisfied, the proof is complete κ ω When κ e t Δt following result 0, g x t β t x t , where β t β t T , t ∈ 0, T , we have the Advances in Difference Equations 13 Corollary 3.2 Suppose that the following conditions hold: i β t > 0, for all t ∈ Iω ; ii u t uΔ t f u t > 0, |u| > d, then 1.7 has at least one ω -periodic solution Acknowledgments The authors... thank the reviewers for their valuable suggestions and useful comments that have led to the present improved version of the original manuscript This research is supported by the Natural Science Foundation of China 60774004, 60904024 , China Postdoctoral Science Foundation Funded Project 20080441126, 200902564 , Shandong Postdoctoral Funded Project 200802018 and supported by Shandong Research Funds Y2008A28... 0 3.18 12 Advances in Difference Equations 0, which implies By assumptions i and ii , we see that |x1 t | ≤ M2 and x2 t Ω2 ⊂ Ω 1 Now, we set Ω {x : x x1 , x2 , |x1 | < M2 1, |x2 | < M3 1} Then Ω1 ⊂ Ω Thus from 3.8 and 3.14 , we see that conditions (B1) and (B2) of Lemma 2.6 are satisfied The remainder is verifying condition (B3) of Lemma 2.6 In order to do it, let J : Im Q → Ker L, J x1 , x2 x1 , x2 . Corporation Advances in Difference Equations Volume 2010, Article ID 584375, 13 pages doi:10.1155/2010/584375 Research Article Existence of Periodic Solutions for p-Laplacian Equations on Time Scales Fengjuan. established for the existence of periodic solutions of this class of nonautonomous scalar dynamic equations on time scales, the approach that authors used in this paper is based on Mawhin’s continuation. systematically explore the periodicity of Li ´ enard type p-Laplacian equations on time scales. Sufficient criteria are established for the existence of periodic solutions for such equations, which generalize