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    Existence and Uniqueness of Solutions to Singular Higher Order Two-point BVPs on Time Scales

    2017-06-05 15:01:17TENGNanMAFuboYUTongMORan

    TENG Nan,MA Fu-bo,YU Tong,MO Ran

    (1.Department of Mathematics,Harbin University,Harbin 150086,China;2.Department of Civil Engineering,Harbin University,Harbin 150086,China)

    Existence and Uniqueness of Solutions to Singular Higher Order Two-point BVPs on Time Scales

    TENG Nan1,MA Fu-bo2,YU Tong2,MO Ran1

    (1.Department of Mathematics,Harbin University,Harbin 150086,China;2.Department of Civil Engineering,Harbin University,Harbin 150086,China)

    This paper investigates the existence and uniqueness of solutions for singular higher order boundary value problems on time scales by using mixed monotone method. The theorems obtained are very general.For the different time scale,the problem may be the corresponding continuous or discrete boundary value problem.

    time scale;boundary value problem;mixed monotone operator;singularity

    §1.Introduction

    Let T be a time scale(nonempty closed subset of R)and[a,b]Tis subset of T such that [a,b]T={t∈T:a≤t≤b},with the subspace topology inherited from the Euclidean topology on R.Open intervals and half-open intervals and so on are defined accordingly.In this paper, we consider the existence and uniqueness of solution to the following singular higher order two-point boundary value problem(BVP,in short)with a parameter λ on time scales

    where q(t)∈Crd((0,σ(1))T,(0,+∞)),f∈C((0,+∞)n?1,(0,+∞))and q may be singular at t=0 and/or t=σ(1)and also f may be singular at x=0.

    When T=R,in particular,then BVP(1.1)is the following differential equation

    where q(t)∈C((0,1),(0,+∞)),f∈C((0,+∞)n?1,(0,+∞))and q may be singular at t=0 and/or t=1 and also f may be singular at x=0.

    The study of higher order continuous and discrete boundary value problems have been studied extensively in the literature(for example,see[1-5,9]).Most of the results told us that the equations had at least single and multiple positive solutions.Vamsi and Baruah[14]gave bounds for solutions to initial-value problems associated with nonlinear singular interface problems by using the method of upper and lower solutions intertwined with monotone iterative technique.

    Time scales can be used in microeconomics models to study behavior which is sometimes continuous and sometimes discrete.A simple example of this continuous-discrete behavior is seen in suppliers’short-run decisions and long-run decisions.Unifying both continuous and discrete model can avoid repeat researches and therefrom we have the capacity to get some different types of models which are neither continuous nor discrete ones that can be effectively described.

    Inspired by the paper[15],we dedicated to the research the boundary value problems on time scales.The principle aim of this paper is to systematically study and unify the existence and uniqueness of solutions for the problem(1.1)by ordinary differential equations and their discrete analogues in form of difference equations and to extend these results to more general time scales.In our approach,specifically,we do not deal with a system of classical ordinary differential equations but,more generally,with a system of dynamical equations on time scales. Above,it is a characteristic and innovation of this paper,which differs from the current available literatures.

    §2.Preliminaries

    In this section,we will give definitions and some lemmas which are useful in proving ourmain results.

    Let G(t,s)be the Green’s function for the boundary value problem

    which is given by

    One can show that

    for t∈[0,σ(1)]T.

    then we have

    Therefore,if y(t)solves BVP(2.5),then x(t)is a solution to BVP(1.1)by(2.4)and if y(t)is a positive solution of(2.5),then

    The following definitions and results can be found in[68].

    Definition 2.1Let E be a real Banach space.A nonempty closed set K?E is called a cone of E if and only if

    (i)a,b∈R,a,b≥0 and x,y∈K implies ax+by∈K;

    (ii)x∈K and-x∈K implies x=0.

    Given a cone P?E,we define a partial order≤on E with respect to P by x≤y if and only if y-x∈P.We will write x<y to indicate that x<y but x/=y,while x?y will stand for y-x∈P?(P?denotes the interior of P).

    Definition 2.2A cone P?E is called normal cone if there is a positive number N>0 such that for all x,y∈E,0≤x≤y implies‖x‖≤N‖y‖.The smallest N is called the normal constant of P.

    Let P be a normal cone of Banach space E and e∈P with‖e‖≤1,e/=θ.Define

    Definition 2.3Assume that A:Qe×Qe→Qe.Now A is said to be mixed monotone if A(x,y)is nondecreasing in x and nonincreasing in y,i.e.,if x1≤x2(x1,x2∈Qe)implies A(x1,y)≤A(x2,y)for any y∈Qeand y1≤y2(y1,y2∈Qe)implies A(x,y1)≥A(x,y2)for any x∈Qe.One says x?∈Qeis a fixed point of A if A(x?,x?)=x?.

    Lemma 2.1Assume that A:Qe×Qe→Qeis a mixed monotone operator and there exists a constant α,0≤α<1,such that

    Then A has a unique fixed point x?∈Qe.Moreover,for any(x0,y0)∈Qe×Qe,

    0<r<1,r is a constant from(x0,y0).

    Lemma 2.2Assume that A:Qe×Qe→Qeis a mixed monotone operator and there exists a constant α∈(0,1)such that(2.7)holds.If x?λis a unique solution of equation

    In order to obtain our main results,we also assume that

    (A1)f(u1,u2,···,un?1)=g(u1,u2,···,un?1)+h(u1,u2,···,un?1),where

    (A2)g is non-decreasing in ui>0,i=1,2,···,n-1,also h is non-increasing in ui>0 for i=1,2,···,n-1.

    (A3)?α∈(0,1)such that

    for ui>0,i=1,2,···,n-1,?t∈(0,σ(1))T.

    (A4)q∈Crd((0,σ(1))T,(0,+∞))satisfies

    §3.Existence and Uniqueness of Solution

    Define a cone by P={x∈E|x(t)≥0,t∈[0,σ(1)]T}and clearly P is a normal cone of the Banach space E.

    Proof Since(2.9)holds,let t?1ui=vi,i=1,2,···,n-1,one has

    Now with vi=1,i=1,2,···,n-1,there is

    From(2.9)and(3.1),one yields

    for t∈(0,σ(1)),ui>0,i=1,2,···,n-1.Similarly,there is

    with ui=1,i=1,2,···,n-1,from(2.8).

    Now,when u1=u2=···=un?1=:ˉu>1,let t=ˉu?1,then

    Set e(t):=t(1-t).It is clear that‖e‖≤1 and we define

    where M>1 is chosen such that

    For any v,w∈Qe,?t∈[0,σ(1)]T,now define

    First we show that Aλ:Qe×Qe→Qe.Let v,w∈Qe,from(3.6)we have

    And from(3.3)~(3.4)we obtain

    Hence,?t∈[0,σ(1)]T,

    On the other hand,for any v,w∈Qe,by(3.5),we have

    Thus we yield

    for t∈[0,σ(1)]T.

    So,Aλis well defined and Aλ(Qe×Qe)?Qe.Next,?l∈(0,1)and?v,w∈Qe,let

    one has

    This completes the proof.

    §4.Applications

    for λ>0,t∈[0,1]T.

    and by calculating directly,we get

    In the same way as in Theorem 3.1,we can obtain the another unique existence result of positive solution to BVP(1.1),under the following assumptions

    (A5)f(u1,u2,···,un?1)=g(u1,u2,···,un?1)·h(u1,u2,···,un?1),where

    (A6)g is non-decreasing in ui>0,i=1,2,···,n-1,also h is non-increasing in ui>0, i=1,2,···,n-1.

    (A7)There exist α,β>0,α+β∈(0,1),such that

    for ui>0,i=1,2,···,n-1,?t∈(0,σ(1))T.

    (A8)q∈Crd((0,σ(1))T,(0,+∞))satisfies

    Example 4.2 Consider the following singular boundary value problem

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    tion:34B16,34B18,34N05

    :A

    1002–0462(2017)01–0049–10

    date:2015-12-12

    Supported by the Foundation for Students Innovative Projects of Heilongjiang Province (201510234012)

    Biography:TENG Nan(1995-),female,native of Hailun,Heilongjiang,an undergraduate of Harbin University,engages in application and modeling of differential equation.

    CLC number:O175.8

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