In this paper, we deal with the existence and uniqueness of the solutions of two-point boundary value problem of fourth-order ordinary differential equation: u4(t)=f(t,u(t),u′(t)), t∈[0,1], u(0)=u′(0)=u′′(1)=u′′′(1)=0, where f:[0,1]×R2→R is a continuous function. The problem describes the static deformation of an elastic beam whose left end-point is fixed and right is freed, which is called slanted cantilever beam. Under some weaker assumptions, we establish a new maximum principle by the perturbation of positive operator and construct the monotone iterative sequence of the lower and upper solutions, and, based on this, we obtain the existence and uniqueness results for the slanted cantilever beam.
1. Introduction
In mechanics, the two-point boundary value problems of fourth-order ordinary differential equations are mainly used to describe the static deformation of elastic beam under external force, and especially a model to study travelling waves in suspension bridges can be furnished by the fourth-order equation of nonlinearity. Due to the different support conditions of elastic beams, a variety of boundary value problems are derived; see [1].
In this paper, we deal with the existence and uniqueness results of solutions to the two-point boundary value problem of fourth-order ordinary differential equation (1)u4t=ft,ut,u′t,t∈0,1,u0=u′0=u′′1=u′′′1=0,where f:[0,1]×R2→R is a continuous function. The problem is called slanted cantilever beam which describes the static deformation of an elastic beam whose left end-point is fixed and right is freed. For the equation, the physical meaning of the first-order derivative u′(t) of unknown function is the slope, which reflects the curving degree of the elastic beam; see [1–5].
There are many results on the cantilever beam equation; see [4–17]. Specially, in [4, 14, 15], Agarwal et al. used the fixed point theorems of cone mapping to research the special case of BVP (1) that the nonlinear term f does not contain the derivative term u′, namely, (2)u4t=ft,ut,t∈0,1,u0=u′0=u′′1=u′′′1=0.In these works, since there is no derivative term, the research about the solutions is simple and feasible relatively.
In [6, 7, 10, 16, 17], for the fourth-order ordinary differential equation with the boundary value condition u(0)=u′(0)=u′′(1)=0, u′′′(1)=μg(u(1)), which means that the left end of the beam is fixed and the right is attached to a bearing device, the existence and multiplicity of solutions have been discussed by using the variational methods and critical point theory.
For the case of BVP (1), in [11], Yao constructed a successively iterative sequence by using the monotone iterative technique and applying the successively approximate method to prove an existence theorem. Recently, in [5], by using the fixed point index theory in cones, Li researched the existence of positive solutions of cantilever beam equation in which the nonlinear term contains all order derivatives of unknown function.
However, there are still many limitations in the study of this problem in recent years. First of all, most conclusions of the existences were obtained only by roughly estimating the properties of the corresponding Green function; secondly, most of the conditions for nonlinear term f are very harsh, so the existence results of the solutions are not optimal.
For the solvability of elastic beam equations with other types of boundary conditions, many results have been obtained; see [18–24] and references therein. Specially, in [23], Li dealt the fourth-order boundary value problem (3)u4t=ft,ut,u′′t,t∈I,u0=u1=u′′0=u′′1=0and obtained the existence and uniqueness of solutions by utilizing the perturbation of positive operator and the monotone iterative technique of upper and lower solutions. It is well known that the monotone iterative method of lower and upper solutions has been widely used in solving the boundary value problem of ordinary differential equations. However, as far as we know, no researchers studied BVP (1) by monotone iterative method of lower and upper solutions.
Motivated by the papers mentioned above, we will use the monotone iterative technique of lower and upper solutions to discuss the existence and uniqueness of BVP (1). It is well known that the theoretical basis of the monotone iterative technique is the maximum principle. It often requires two aspect of works for this method. One is to construct the iterative sequence and judge its monotonicity, and the other is to verify the convergence of the constructed sequence. Generally, For the case of BVP (2), the nonlinear item f=f(t,u(t)), if the linear differential operator at the left satisfies the maximum principle, then the monotone iterative technique is feasible; see [18–20]. However, in BVP (1), the nonlinear term contains the derivative; the general maximum principle cannot guarantee the monotonicity of the iterative sequence. Therefore, in order to ensure the feasibility of the monotone iterative technique, we should strengthen the maximum principle.
The purpose of this paper is to construct a new maximum principle for fourth-order differential operator (4)L4u=u4+Nu′+Mu,where M,N are constants satisfying (5)N2+M3≤1,M,N≥0and establish the monotone iterative technique in the case of the lower and upper solutions existing in BVP (1). To the best of our knowledge, using this method to solve the problem of the solvability of cantilever beam equation is rare. It means that our conclusions are new and meaningful.
The paper is organized as follows. Section 2 provides the preliminary results which are used in theorems stated and proved in the article, and Section 3 presents the main results and its proof of the article.
2. Preliminaries
In this section, we introduce some basic concepts and preliminary facts which are used in this paper.
Let I=[0,1], C(I), be a continuous function space endowed the maximum norm u=maxt∈Iut, Cn(I)(n=1,2,3,4) are n-order continuous differentiable function spaces which are defined in I, and C+(I) denote a cone in the form of all nonnegative functions in C(I). Evidently, C+(I)={u∈C(I)∣u(t)≥0,t∈I}.
Let constants M,N satisfy the expression (5). In order to study the existence of solutions of the BVP (1), we establish a new maximum principle for the differential operator (4). To this end, we consider the corresponding fourth-order linear boundary value problem (LBVP) (6)u4t+Nu′t+Mut=ht,t∈I,u0=u′0=u′′1=u′′′1=0.Assume that v(t)=u′(t); then we have (7)ut=∫0tvsds≔T0vt. Evidently, T0=1. Therefore, the fourth-order LBVP (6) is equivalent to the following third-order boundary value problem: (8)v3t+Nvt+MT0vt=ht,t∈I,v0=v′1=v′′1=0.
We have known that, for any h∈C(I), the third-order linear boundary value problem (9)v3t=ht,t∈I,v0=v′1=v′′1=0has a unique solution v∈C3(I), which can be expressed as (10)vt=∫01Gt,shsds≔Sht,where G(t,s) is the Green function of LBVP (9) given by the following expressions: (11)Gt,s=ts-12t2,0≤t≤s≤1,12s2,0≤s≤t≤1.Clearly, G(t,s) is continuous, and the following lemma is established.
Lemma 1.
G(t,s) has the following properties:
G(t,s)>0, for any 0<t,s<1.
tG(s,s)≤G(t,s)≤maxt∈IG(t,s)=G(s,s), for any 0≤t,s≤1.
G(t,s)≤st, for any 0≤t,s≤1.
Proof.
From the expression of (11), it follows that (a) holds.
(b) For 0≤t≤s≤1, we have (12)Gt,s-Gs,s=-12s-t2≤0,Gt,s-tGs,s=st-12t2-12ts2=12ts-t+12st1-s≥0. For 0≤s≤t≤1, (13)Gt,s=12s2=Gs,s≥tGs,s.
(c) From the expression (11), for any t,s∈[0,1],G(t,s)≤st holds obviously.
This completes the proof of Lemma 1.
From Lemma 1, we can obtain the following result which is needed in the proof of our main results.
Lemma 2.
The solution operator S:C(I)→C(I) of LBVP (9) is the completely continuous linear operator, and its norm satisfies S≤1/6. Furthermore, if h∈C+(I), then Sh(t)≥tSh, for every t∈I.
Proof.
From (10), we can easily obtain that the solution operator S:C(I)→C(I) of LBVP (9) is a completely continuous linear operator.
For any h∈C(I), by (10) and (11), we obtain (14)Sht≤∫01Gt,sds·h=16t3-3t2+3th≤16h,t∈I. It is easy to see that Sh≤1/6h, which implies that S≤1/6 holds.
Furthermore, for h∈C+(I), from (10) and the second inequality of Lemma 1(b), we get (15)Sht≤∫01Gs,shsds,t∈I.It follows that (16)Sh≤∫01Gs,shsds.From Lemma 1(b), we have (17)Sht=∫01Gt,shsds≥t∫01Gs,shsds≥tSh. This completes the proof of Lemma 2.
In order to establish the new maximum principle, we also need to prove the following lemma.
Lemma 3.
Let there exist constants M and N satisfying the assumption (5); then LBVP (6) has a unique solution u=Th∈C4(I) for any h∈C(I), and the solution operator T:C(I)→C1(I) is completely continuous. Specifically, when h∈C+(I), then the solution u=Th satisfies u(t)≥0,u′(t)≥0,t∈I.
Proof.
According to the above analysis, if there exists the unique solution v∈C3(I) of LBVP (8), then u=T0v∈C4(I) is the unique solution of LBVP (6). By the Lemma 2, LBVP (8) is equivalent to the operator equation (18)J+NS+MST0vt=Sht,where J is the unit operator in C(I). By Lemma 2, it follows that (19)NS+MST0≤NS+MS·T0≤N6+M6≤N4+M6=12N2+M3≤12. Therefore, J+NS+MST0 creates bounded inverse operator. According to the Neumann expansion, we can obtain that(20)J+NS+MST0-1=∑n=0∞-1nNS+MST0n=∑n=0∞-1nNS+MST02nJ-NS-MST0; its norm satisfies (21)J+NS+MST0-1≤11-NS+MST0≤2.Therefore, the operator equation (18) has a uniqueness solution (22)v=J+NS+MST0-1Sh≔Bh.Thus, LBVP (6) has the uniqueness solution u=T0v=T0Bh≔Th, where B=(J+NS+MST0)-1S,T=T0B. Since the operator S:C(I)→C(I) is completely continuous and (J+NS+MST0)-1 is a bounded linear operator, then the operator B:C(I)→C(I) is completely continuous. Thus, according to the boundedness of T0:C(I)→C1(I), we can get that T:C(I)→C1(I) is a completely continuous operator.
Now, we prove that, for any h∈C+(I), the solution u=Th of LBVP (6) satisfies u≥0,u′≥0.
Since T0 and S are the positive operators in C(I), and Sh≤Sh, then from the definition of operator T0, we have T0Sh≤tSh, and by Lemma 2(c), it is obvious that (23)NS+MST0Sh=NSSh+MST0Sh≤NS1+MSsSh=N∫01Ht,sds+M∫01sHt,sdsSh≤N2t+M3tSh=N2+M3Sht, for any t∈I. By Lemma 2, we can obtain (24)J-NS-MST0Sh=Sh-NS+MST0Sh≥Sht-N2+M3Sht=1-N2+M3Sht≥0, for any t∈I. Since T0 and S are the positive operators, we can obtain that (25)Bh=J+NS+MST0-1Sh=∑n=0∞NS+MST02nJ-NS-MST0Sh≥0. Therefore, the solution of LBVP (6) satisfies u=T0Bh≥0, and u′=Bh≥0. This completes the proof of Lemma 3.
According to the conclusion of Lemma 3, the following maximum principle can be obtained.
Lemma 4.
Let there exist constants M and N satisfying the assumption (5), if u∈C4(I) satisfies (26)u4t+Nu′t+Mut≥0,t∈I,u0≥0,u′0≥0,u′′1≥0,u′′′1≤0; then u(t)≥0,u′(t)≥0 for any t∈I.
3. Main Results
Now, we are in the position to state and prove our main results. We will apply monotone iterative method of the lower and upper solutions to obtain the existence and uniqueness of solutions for cantilever beam equation (1). To this end, we define the lower and upper solutions of BVP (1).
Definition 5.
If α(t)∈C4(I) satisfies (27)α4t≤ft,αt,α′t,t∈I,α0≤0,α′0≤0,α′′1≤0,α′′′1≥0,then α(t) is called a lower solution of BVP (1). If the inequality of (27) is inverse, then α(t) is called an upper solution of BVP (1).
Theorem 6.
Let f:I×R×R→R be continuous, and there are lower and upper solutions α and β for BVP (1), satisfying α≤β,α′≤β′. If f satisfies the following condition:
there exist positive constants M and N satisfying (5), such that (28)ft,u2,v2-ft,u1,v1≥-Mu2-u1-Nv2-v1,
for arbitrary t∈I,u1,u2∈[α,β],v1,v2∈[α′,β′],u2≥u1,v2≥v1,
then BVP (1) has one maximal solution u¯ and minimal solution u_ between α and β.
Proof.
Let D={u∈C1(I)∣α≤u≤β,α′≤u′≤β′}, Clearly, D is a bounded nonempty convex closed set in C1(I).
For any u∈D, we define an operator F:D→C(I) as follows: (29)Fut=ft,ut,u′t+Nu′t+Mut. According to the continuity of f, it is easy to see that F is the continuous bounded operator in C(I). Let T be the solution operator of LBVP (6); then the solution of BVP (1) in D is equivalent to the fixed point of the composition operator Q=T∘F:D→C1(I). We can easily obtain that operator Q as completely continuous by the complete continuity of T and the boundedness of F. In the following, we will take four steps to prove the conclusion.
Step 1. We prove that Q(D)⊂D.
To this end, we let x=Qu for every u∈D. And define h=F(u), and then x=Th is the solution of LBVP (6). Thus, x∈C4(I) satisfy (30)x4t+Nx′t+Mxt=ft,ut,u′t+Nu′t+Mut,t∈I,x0=x′0=x′′1=x′′′1=0.Then by the definition of the lower and upper solutions and the assumption (F1), it is clear that (31)x-α4+Nx-α′+Mx-α≥ft,u,u′-ft,α,α′+Nu-α′+Mu-α≥-Mu-α-Nu-α′+Nu-α′+Mu-α=0,∀t∈I,β-x4+Nβ-x′+Mβ-x≥ft,β,β′-ft,u,u′+Nβ-u′+Mβ-u≥-Mβ-u-Nβ-u′+Nβ-u′+Mβ-u=0,∀t∈I. By the boundary conditions, we can get that (32)x-α0≥0,x-α′0≥0,x-α′′1≥0,x-α′′′1≤0,β-x0≥0,x-α′0≥0,x-α′′1≥0,x-α′′′1≤0. Applying Lemma (10) to x-α and β-x, we have (33)x-α≥0,x-α′≥0;β-x≥0,β-x′≥0, which means α≤x≤β, α′≤x′≤β′ in I. Therefore, we can conclude that Q(D)⊂D.
Step 2. We show that if u1,u2∈D satisfy α≤u1≤u2≤β,α′≤u1′≤u2′≤β′, then Qu1≤Qu2,Qu1′≤Qu2′ holds.
In fact, similar to the first step, let x1=Qu1,x2=Qu2, and then by the assumption (F1), we can obtain (34)x2-x14+Nx2-x1′+Mx2-x1=ft,u2,u2′-ft,u1,u1′+Nu2′-u1′+Mu2-u1≥-Mu2-u1-Nu2′-u1′+Nu2′-u1′+Mu2-u1≥0,∀t∈I. By the boundary conditions, we can get that (35)x2-x10≥0,x2-x1′0≥0,x2-x1′′1≥0,x2-x1′′′1≤0;then applying Lemma (10) to x2-x1, we have (36)x2-x1≥0,x2-x1′≥0,∀t∈I, which means that Qu2≥Au1,Qu2′≥Qu1′.
Step 3. We demonstrate that there exist solutions between α and β.
We use α and β as the initial element for constructing iterative sequence (37)αn=Qαn-1,βn=Qβn-1,n=1,2,…
According to the definition of the operator Q, Steps 1 and 2, we can easily see that (38)α0≤α1≤⋯≤αn≤βn≤⋯≤β1≤β0,α0′≤α1′≤⋯≤αn′≤βn′≤⋯≤β1′≤β0′,which means that {αn} and {βn} are monotone increasing and decreasing in the order interval [α,β], respectively; {αn′} and {βn′} are also monotonous in the order interval [α′,β′].
By the compactness of Q, we know that {αn},{βn}⊂Q(D) are the relatively compact sets in C1(I), and, therefore, they have the uniformly convergent subsequence in C1(I). Then by (38), {αn},{βn},{αn′},{βn′} are all uniformly convergent in I; therefore, {αn} and {βn} are uniformly convergent in C1(I), which means there exist u_ and u¯∈C1(I), such that αn→u_,βn→u¯. Since D is a convex closed set in C1(I), it is obvious that u_,u¯∈D. In the expression (37), we let n→∞, and then, from the continuity of Q, we can easily see u_=Qu_,u¯=Qu¯, for any t∈I. Thus, u_ and u¯ are the solutions of BVP (1) between α and β.
Step 4. We testify that u_ and u¯ are the minimal and maximal solutions of BVP (1) between α and β, respectively.
Let u∈D be an arbitrary solution of LBVP (6); then u(t) satisfies (39)α≤u≤β,α′≤u′≤β′. By Step 2, using Q acting n times for the last expression, it can be easily obtained that (40)αn≤u≤βn,αn′≤u′≤βn′,n=1,2,….Taking n→∞, we can see (41)u_≤u≤u¯,u_′≤u′≤u¯′. It can be easily obtained that u_ and u¯ are the minimum and maximum solutions of BVP (1) between α and β, respectively.
This completes the proof of Theorem 6.
From the above proof process, the next corollary can be easily obtained.
Corollary 7.
Let f:I×R×R→R be continuous, and there exist lower and upper solutions α and β for BVP (1), satisfying α≤β,α′≤β′. If f satisfies the assumption (F1), we use α and β as the initial elements to construct iterative sequences {αn} and {βn} by linear iterative equation (42)un4t+Nun′+Mun=ft,un-1t,un-1′t+Nun-1′+Mun-1,t∈I,un0=un′0=un′′1=un′′′1=0;then we can obtain that (43)limn→∞αnt=u_t,limn→∞βnt=u¯t,limn→∞αn′t=u_′t,limn→∞βn′t=u_t uniformly hold for arbitrary t∈I, where u_ and u¯ are the minimal and maximal solutions of BVP (1) in the set (44)D=u∈C1I∣α≤u≤β,α′≤u′≤β′, respectively.
Theorem 6 gives the existence of the solution of BVP (1). Now, we can further discuss the uniqueness result of the solutions by strengthening the assumption (F1).
Theorem 8.
Let f:I×R×R→R be continuous, and there exist lower and upper solutions α and β for BVP (1), satisfying α≤β,α′≤β′. If f satisfies the assumption (F1) and the following condition:
there exist positive constants C1 and C2 satisfying (45)C1+C2+M+N<3,
such that (46)ft,u2,v2-ft,u1,v1≤C1u2-u1+C2v2-v1,
for every t∈I,u1,u2∈D,v1,v2∈[α′,β′], u2≥u1,v2≥v1,
then BVP (1) has a unique solution u∗ in D, and, for every u0∈D, the monotone iterative sequence un constructed by (42) uniformly converges to the unique solution u∗.
Proof.
By the proof of Theorem 6, when the assumption (F1) holds, then the BVP (1) has maximal solution u¯ and minimal solution u_ in D, and for every solution u∈D, we have u_≤u≤u¯,u_′≤u′≤u¯′. Next, we need to prove that u_=u¯.
According to the proof of Lemma (9), the operator B:C(I)→C(I) defined by (22) is a positive linear operator, and its norm satisfies (47)B≤J+NS+MST0-1·S≤2×16=13.Since T=T0B, for any h∈C(I), we have Th′=Bh.
Assuming that {αn},{βn} are the monotone iterative sequences constructed in Theorem 6, by the assumptions (F1) and (F2) and the positivity of operator B, we can see (48)βn′-αn′=Qβn-1′-Qαn-1′=TFβn-1′-TFαn-1′=BFβn-1-BFαn-1=BFβn-1-Fαn-1=Bft,βn-1,βn-1′-ft,αn-1,αn-1′+Mβn-1-αn-1+Nβn-1′-αn-1′≤BC1+Mβn-1-αn-1+C2+Nβn-1′-αn-1′=C1+MBT0βn-1′-αn-1′+C2+NBβn-1′-αn-1′=C1+MBT0+C2+NBβn-1′-αn-1′, which implies that (49)βn′-αn′≤C1+MT0+C2+NB·βn-1′-αn-1′≤C1+C2+M+NB·βn-1′-αn-1′. Therefore, we can get (50)βn′-αn′≤C1+C2+M+NB·βn-1′-αn-1′≤C1+C2+M+N2B2·βn-2′-αn-2′≤⋯≤C1+C2+M+NnBn·β0′-α0′. By (47) and the assumption (F2), we have (51)βn′-αn′≤C1+C2+M+N3n·β0′-α0′⟶0n⟶∞. Thus, we have (52)βn-αn=T0βn′-αn′≤T0·βn′-αn′⟶0n⟶∞.Therefore, by the conclusions of Corollary 7, we can obtain (53)u_=limn→∞αn=limn→∞βn=u¯. Consequently, u∗=u_=u¯ is the unique solution of BVP (1).
Now, we need to testify that the monotone iterative sequence un constructed by (42) uniformly converges to the unique solution u∗.
Assuming u0∈D, then the monotone iterative sequence un used u0 as the initial element constructed by (42) satisfying un=Aun-1,n=1,2,…. According to Step 2 of the proof process of Theorem 6, it is easy to see that (54)αn≤un≤βn,αn′≤un′≤βn′,n=0,1,2,…. Taking n→∞, it follows that un→u∗ in C1(I). Therefore, the conclusion is established.
Finally, we give a numerical example to illustrate our theoretical results.
Example 1.
Consider the following nonlinear problem: (55)u4t=13sint·ut+13cost·u′t+12et,t∈0,1,u0=u′0=u′′1=u′′′1=0.
Clearly, α(t)≡0 is a lower solution of problem (55). Letting β(t)=et, we can obtain that (56)13sint·βt+13cost·β′t+12et≤23sint+π4et+12et≤23+12et≤et=β4t; it is means that β(t)=et is a upper solution of problem (55).
On the other hand, for arbitrary t∈[0,1], when u1,u2∈[0,et],v1,v2∈[0,et], and u2≥u1,v2≥v1, we can easily obtain (57)13sint·u2t+13cost·v2t-13sint·u1t+13cost·v1t=13sintu2t-u1t+13costv2t-v1t≥-13u2t-u1t-13v2t-v1t, which implies that (58)ft,ut,u′t=13sint·ut+13cost·u′t+12et satisfies the condition (F1) for M=N=1/3. Then, by Theorem 6, problem (55) has at least one maximal solution u¯ and minimal solution u_ between 0 and et.
Furthermore, it is obvious that (59)13sintu2t-u1t+13costv2t-v1t≤13u2t-u1t+13v2t-v1t,which implies that f(t,u(t),u′(t)) satisfies the condition (F2) for C1=C2=M=N=1/3. Then, by Theorem 8, the problem (55) has a unique solution u∗ which satisfies 0≤u∗≤et,0≤u∗′≤et.
Conflicts of Interest
The authors declare that they have no conflicts of interest.
GuptaC. P.Existence and uniqueness theorems for the bending of an elastic beam equation1988264289304MR92297610.1080/00036818808839715Zbl0611.340152-s2.0-84950192244AftabizadehA. R.Existence and uniqueness theorems for fourth-order boundary value problems19861162415426MR84280810.1016/S0022-247X(86)80006-32-s2.0-0001414103GuptaC. P.Existence and uniqueness results for the bending of an elastic beam equation at resonance19881351208225MR96081410.1016/0022-247X(88)90149-7Zbl0655.730012-s2.0-38249027575AgarwalR. P.O'ReganD.Multiplicity results for singular conjugate, focal, and (n,p) problems2001170114215610.1006/jdeq.2000.3808MR1813103LiY.Existence of positive solutions for the cantilever beam equations with fully nonlinear terms201627221237MR340052510.1016/j.nonrwa.2015.07.016Zbl1331.740952-s2.0-84939857395CabadaA.TersianS.Multiplicity of solutions of a two point boundary value problem for a fourth-order equation20132191052615267MR300948510.1016/j.amc.2012.11.066Zbl1294.340162-s2.0-84872138418HadjianA.RamezaniM.Existence of infinitely many solutions for fourth-order equations depending on two parameters2017117110MR3651914AndersonD. R.HoffackerJ.Existence of solutions for a cantilever beam problem20063232958973MR226015510.1016/j.jmaa.2005.11.011Zbl1115.340192-s2.0-33750624603DangQ. A.NgoT. K.Existence results and iterative method for solving the cantilever beam equation with fully nonlinear term2017365668MR362123010.1016/j.nonrwa.2017.01.001Zbl1362.340362-s2.0-85010002215BonannoG.ChinnìA.TersianS. A.Existence results for a two point boundary value problem involving a fourth-order equation20152015192-s2.0-8493019649410.14232/ejqtde.2015.1.33Zbl1349.34070YaoQ.Monotonically iterative method of nonlinear cantilever beam equations20082051432437MR246664810.1016/j.amc.2008.08.044Zbl1154.740212-s2.0-54049097026YaoQ.Solvability of singular cantilever beam equation20082419399MR2419106YaoQ.Local existence of multiple positive solutions to a singular cantilever beam equation20103631138154MR255904810.1016/j.jmaa.2009.07.043Zbl1191.340312-s2.0-70350708130AgarwalR. P.O'ReganD.Twin solutions to singular boundary value problems200012872085209410.1090/S0002-9939-00-05320-XMR16642972-s2.0-23044518424Zbl0946.34020AgarwalR. P.O'ReganD.LakshmikanthamV.Singular (p,n-p) focal and (n,p) higher order boundary value problems2000422, Ser. A: Theory Methods21522810.1016/S0362-546X(98)00341-1MR1773979YangL.ChenH.YangX.The multiplicity of solutions for fourth-order equations generated from a boundary condition2011249159916032-s2.0-7995612850410.1016/j.aml.2011.04.008SongY.A nonlinear boundary value problem for fourth-order elastic beam equations2014201411112-s2.0-8491939181210.1186/s13661-014-0191-6Zbl1325.34026CabadaA.The method of lower and upper solutions for second, third, fourth, and higher order boundary value problems19941852302320MR128305910.1006/jmaa.1994.1250Zbl0807.340232-s2.0-0000934317CabadaA.CidJ. A.SanchezL. s.Positivity and lower and upper solutions for fourth order boundary value problems20076751599161210.1016/j.na.2006.08.002MR2323306De CosterC.SanchezL.Upper and lower solutions, ambrosetti-prodi problem and positive solutions for fourth order O.D.E1994145782MR1275354MaR.ZhangJ.FuS.The method, of lower and upper solutions for fourth-order two-point boundary value problems1997215415422YangY. S.Fourth-order two-point boundary value problems19881041175180MR95806210.1090/S0002-9939-1988-0958062-3Zbl0671.340162-s2.0-8496851888810.2307/2047481LiY.A monotone iterative technique for solving the bending elastic beam equations2010217522002208MR272796610.1016/j.amc.2010.07.020Zbl1342.340392-s2.0-77957293941BaiZ.The upper and lower solution method for some fourth-order boundary value problems20076761704170910.1016/j.na.2006.08.009MR2326022