Positive Solutions for a Mixed-Order Three-Point Boundary Value Problem for p-Laplacian

Definition 1. Let E be a real Banach space. A nonempty closed convex set K ⊂ E is called cone if

• (1)

  x ∈ K, λ ≥ 0 then λx ∈ K,

• (2)

  x ∈ K, −x ∈ K then x = 0.

Definition 2. An operator is called completely continuous if it is continuous and maps bounded sets into precompact sets.

Remark 3. By the positive solution of (1) and (2) we understand a function u(t) which is positive on [0,1] and satisfies the differential equation (1) and the boundary conditions (2).

We will consider the Banach space E = C[0,1] equipped with standard norm:

The proof of existence of solution is based upon an application of the following theorem.

Theorem 4 (see [7], [8].)Let E be a Banach space and let K be a cone of E. For r > 0, define K_r = {u ∈ K :   ∥u∥   ≤   r} and assume that T : K_r → K is a completely continuous operator such that Tu ≠ u for all u ∈ ∂K_r.

• (1)

  If ∥Tu∥   ≤   ∥u∥ for all u ∈ ∂K_r, then i(T, K_r, K) = 1.

• (2)

  If ∥Tu∥   ≥   ∥u∥ for all u ∈ ∂K_r, then i(T, K_r, K) = 0.

Lemma 5 (see [9].)Let n ∈ ℕ with n ≥ 2, n − 1 < α ≤ n. If u ∈ Cⁿ⁻¹[a, b] and $$, then

holds on (a, b).

Lemma 6. The three-point boundary value problem (1)-(2) has a unique solution

where

Proof. Integrating both sides of (1) on [0,1], we have

So From Lemma 5, we have From (2), A = 0 and C = 0.

Now, consider the following:

by the boundary value condition u^′(1) = γu^′(η), we have so Splitting the second integral in two parts of the form we have k = γt; thus, therefore, This completes the proof.

Lemma 7. Let β ∈ (0,1) be fixed. The kernel, G₁(t, s), satisfies the following properties.

• (1)

  0 ≤ G₁(t, s) ≤ G₁(1, s) for all s ∈ (0,1),

• (2)

  min _β≤t≤1G₁(t, s) ≥ βG₁(1, s) for all s ∈ [0,1].

Proof. (1) As 2 < α ≤ 3 and 0 ≤ s ≤ t ≤ 1, we have

thus, G₁(t, s) > 0. Note ∂G₁(t, s)/∂t ≥ 0 then, G₁(t, s) is increasing as a function of t; therefore,

(2) For β ≤ t ≤ 1, we have

where (a) If 0 < s ≤ β, on the other hand, Since 2 < α ≤ 3 and

• (i)

  α − 1 > 1, β ∈ (0,1)⇒β^α−1 < β,

• (ii)

  s ≤ β⇒s/β ≤ 1⇒1 − (s/β) ≥ 0,

• (iii)

  β < 1⇒1 < 1/β⇒−s(1/β) < −s⇒1 − s(1/β) < 1 − s;

thus, we have

From (20), we obtain It follows from (20), (21), and (23), that item 2 in the proof hold.

(b) If β ≤ s < 1,

It follows from (24) that item 2 in the proof holds.

Lemma 8 (see [10].)The unique solution u(t) of (1), (2) is nonnegative and satisfies

Remark 9. By Lemma 6, the problem (1)-(2) has a positive solution u(t) if and only if u is a fixed point of T.

Lemma 10. T is completely continuous and T(K)⊆K.

Proof. By Lemma 8, T(K)⊆K. In view of the assumption of nonnegativeness and continuity of functions G_i(x, y) with i = 1,2 and a(t)f(t, u(t)), we conclude that T : K → K is continuous.

Let Ω⊆K be bounded; that is, there exists M > 0 such that ∥u∥   ≤   M for all u ∈ Ω.

Let

Then from u ∈ Ω and from Lemmas 6 and 7, we have

Hence, T(Ω) is bounded.

On the other hand, let u ∈ Ω, t₁, t₂ ∈ [0,1] with t₁ < t₂; Then

The continuity of G₁ implies that the right-side of the above inequality tends to zero if t₂ → t₁. Therefore, T is completely continuous by Arzela-Ascoli theorem.

We introduce the notation

where a, b = 0⁺, ∞. Consider the following:

Theorem 11. Suppose that conditions (H1) and (H2) hold. Assume that f also satisfy

•  

  (A₁)  f(t, u)≥(mr) ^p−1, βr ≤ u ≤ r, β ≤ t ≤ 1,

•  

  (A₂)  f(t, u)≤(MR) ^p−1, 0 ≤ u ≤ R, 0 ≤ t ≤ 1,

where m ∈ (Λ₁, ∞) and M ∈ (0, Λ₂). Then (1)-(2) has at least one positive solution u such that r ≤   ∥u∥   ≤ R.

Proof. Without loss of generality, we suppose that r < R. For any u ∈ K, we have

We define two open subsets of E, For u ∈ ∂Ω₁, by (33), we have For t ∈ [β, 1], by (A₁), (27), and Lemma 7, we have Therefore, Then by Theorem 4,

On the other hand, as u ∈ ∂Ω₂, we have

thus, by (A₂), (27), Lemma 7, and (29), we have Therefore, Then by Theorem 4, By (38) and (42): Then, T has a fixed point $$, u is positive solution of problem (1)-(2), and r <   ∥u∥   < R.

Corollary 12. Suppose that conditions (H1) and (H2) hold. Assume that f also satisfy

•  

  (A₃)  f_∞ = λ ∈ ((2Λ₁/β) ^p−1, ∞),

•  

  (A₄)  f⁰ = ψ ∈ [0, (Λ₂/2) ^p−1).

Then (1)-(2) has at least one positive solution u such that r ≤ ∥u∥ ≤ R.

Proof. By (A₄), for ɛ = (Λ₂/2) ^p−1 − ψ, there exists a suitably small positive number H₁, as 0 < u ≤ H₁ and 0 ≤ t ≤ 1, such that

Let R = H₁ and M = (Λ₂/2)∈(0, Λ₂), then, by (44), condition (A₂) holds.

By (A₃), for ɛ = λ − (2Λ₁/β) ^p−1, there exists a sufficiently large r ≠ R such that

Thus, when βr ≤ u ≤ r, one has Let m = 2Λ₁ ∈ (Λ₁, ∞). Then, by (46), condition (A₁) holds.

Hence, from Theorem 11 the desired result hold.

Corollary 13. Suppose that conditions (H1) and (H2) hold. Assume that f also satisfy

•  

  (A₅)  f₀ = λ ∈ ((2Λ₁/β) ^p−1, ∞),

•  

  (A₆)  f^∞ = ψ ∈ [0, (Λ₂/2) ^p−1).

Then (1)-(2) has at least one positive solution u such that r ≤ ∥u∥ ≤ R.

Proof. By (A₅), for ɛ = λ − (2Λ₁/β) ^p−1, there exists a sufficiently small r > 0, such that

Thus, when βr ≤ u ≤ r, we have Let m = 2Λ₁ ∈ (Λ₁, ∞). Then by (48), condition (A₁) holds.

By (A₆), for ɛ = (Λ₂/2) ^p−1 − ψ, there exist a sufficiently large H₂ ≠ r such that

We consider the following two cases.

(a) Suppose that f(t, u) is unbounded, then we know from (H1) that there is a R ≠ r  (>H₂) such that

Since R > H₂, then from (49) and (50) we have Letting M = (Λ₂/2)∈(0, Λ₂), we have Thus, (A₂) holds.

(b) Suppose that f(t, u) is bounded, say

In this case, taking sufficiently large R ≥ (2/Λ₂)L, then letting M = Λ₂/2 ∈ (0, Λ₂), we have Thus, (A₂) holds.

Hence, from Theorem 11 the desired result holds.

Definition 14. A map α : K → [0, +∞) is said to be a nonnegative continuous concave functional on a cone K of a real Banach space E if α is continuous and

for all x, y ∈ K and t ∈ [0,1].

Theorem 15 (see [11].)Suppose $$ is completely continuous and suppose that there exists a concave positive functional ψ on K such that ψ(u) ≤ ∥u∥ for $$. Suppose that there exist constants 0 < a < b < d ≤ c such that

• (B1)

  {u ∈ K(ψ, b, d) : ψ(u) > b} ≠ ∅ and ψ(Tu) > b if u ∈ K(ψ, b, d),

• (B2)

  ∥Tu∥ < a if u ∈ K_a,

• (B3)

  ψ(Tu) > b for u ∈ K(ψ, b, c) with ∥Tu∥ > d.

Then, T has at least three fixed points u₁, u₂, and u₃ such that ∥u₁∥ < a, b < ψ(u₂) and ∥u₃∥ > a with ψ(u₃) < b.

Theorem 16. Suppose that there exist a, b, c with 0 < a < βb < b ≤ c such that

• (C1)

  f(t, u)<(aΛ₂) ^p−1, (t, u)∈[0,1]×[0, a],

• (C2)

  f(t, u)>(bΛ₁) ^p−1, (t, u)∈[β, 1]×[βb, b],

• (C3)

  f(t, u)<(cΛ₂) ^p−1, (t, u)∈[0,1]×[0, c].

Then (1)-(2) has at least three positive solutions.

Proof. By Lemma 10, T : K → K is completely continuous.

Let

It is obvious that ψ is a nonnegative continuous concave functional on K with ψ(u) ≤ ∥u∥, for $$. Now we will show that the conditions of Theorem 15 are satisfied. For $$, then ∥u∥ ≤ c. For t ∈ [0,1] by (27), (29), and (C3), one has This implies $$. By the same method, if $$, then we can get ∥Tu∥ < a and therefore (B2) is satisfied. Next, we assert that {u ∈ K(ψ, βb, b) : ψ(u) > βb} ≠ ϕ and ψ(Tu) > βb for all u ∈ K(ψ, βb, b). In fact, the constant function On the other hand, for u ∈ K(ψ, βb, b), we have Thus, in view of (27), Lemma 7, and (C2), one has as required and therefore (B1) is satisfied.

Finally, we assert that if u ∈ K(ψ, βb, c) with ∥Tu∥ > b then ψ(u) > βb. To see this, suppose that u ∈ K(ψ, βb, c) and ∥Tu∥ > b, then it follows from Lemma 10 that

Thus, (B3) is satisfied.

Therefore, by the conclusion of Theorem 15, the operator T has at least three fixed points. This implies that (1)-(2) has at least three solutions.

Example 1. Consider the boundary value problem with p-Laplacian:

where α = 5/2, η = 1/2, γ = 8/9, β = 1/2, p = 3/2, q = 3, f(t, u) = au^1/2e^2u/(b + e^u + e^2u), a(t) = (1/4)t^−1/2, and $$, $$.

Then

Next, Then, for a = 5 we have f_∞ ∈ ((2Λ₁/β) ^p−1, ∞), so condition (A₃) holds.

Now, Consider

Then, for a = 5 and b = 8 we have f⁰ ∈ [0, (Λ₂/2) ^p−1), so condition (A₄) holds. Therefore, by Corollary 12, (63) has at least one positive solution.

Example 2. Consider the boundary value problem with p-Laplacian:

where α = 5/2, η = 1/2, γ = 8/9, β = 1/2, p = 3/2, q = 3, a(t) = (1/4)t^−1/2, $$, and $$.

Let

By Example 1, we have Λ₁ ≈ 4.873999426 and Λ₂ ≈ 0.5908179503.

Choosing a = 1/14, b = 18, and c = 1296, then

Then the conditions (C1)–(C3) are satisfied. Therefore, it follows from Theorem 16 that (67) has at least three positive solutions u₁, u₂, and u₃ such that