Note on the conformable boundary value problems: Sturm’s theorems and Green’s function

Martínez, F.; Martínez, I.; Kaabar, M. K. A.; Paredes, S.; Martínez, F.; Martínez, I.; Kaabar, M. K. A.; Paredes, S.

doi:10.31349/revmexfis.67.47

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Revista mexicana de física

versión impresa ISSN 0035-001X

Rev. mex. fis. vol.67 no.3 México may./jun. 2021 Epub 21-Feb-2022

https://doi.org/10.31349/revmexfis.67.47

Research

Gravitation, Mathematical Physics and Field Theory

Note on the conformable boundary value problems: Sturm’s theorems and Green’s function

F. Martínez^a

I. Martínez^a

M. K. A. Kaabar^b

S. Paredes^a

^{^a}Department of Applied Mathematics and Statistics, Technological University of Cartagena, Spain. Tel: +34968325586; f.martinez@upct.es

^{^b}Department of Mathematics and Statistics, Washington State University, Pullman, WA, 99163, USA.

Abstract

Recently, the conformable derivative and its properties have been introduced. In this paper, we propose and prove some new results on conformable Boundary Value Problems. First, we introduce a conformable version of classical Sturm’s separation, and comparison theorems. For a conformable Sturm-Liouville problem, Green’s function is constructed, and its properties are also studied. In addition, we propose the applicability of the Green’s Function in solving conformable inhomogeneous linear differential equations with homogeneous boundary conditions, whose associated homogeneous boundary value problem has only trivial solution. Finally, we prove the generalized Hyers-Ulam stability of the conformable inhomogeneous boundary value problem.

Keywords: Conformable fractional derivative; conformable fractional integral; conformable fractional differential equations; Sturm´s theorems; Green’s function

PACS: 02.30.Hq; 02.30.Gp; 02.90. + p

1.Introduction

The idea of fractional derivative was first raised by L’Hospital in 1695. Since then, several related new definitions have been proposed. The most common ones are Riemann-Liouville and Caputo definitions. For more information about the most known fractional definitions, we refer to ¹^,². A new definition of fractional derivative and fractional integral has been recently proposed by Khalil et al. in ³. As a result, several important elements of the mathematical analysis of functions of a real variable have been formulated such as: chain rule, fractional power series expansion and fractional integration by parts formulas, Rolle’s Theorem, and Mean Value Theorem ³^-⁵^,⁴⁰. The conformable partial derivative of the order α∈(0.1] of the real-valued functions of several variables and conformable gradient vector are also defined. In addition, a conformable version of Clairaut’s Theorem for partial derivative is investigated in ⁶. In ⁷, conformable Jacobian matrix is defined, and chain rule for multivariable conformable derivative is proposed. In ⁸, the conformable version of Euler’s Theorem on homogeneous is introduced. Furthermore, in a short time, various research studies have been conducted on the theory and applications of fractional differential equations in the context of this newly introduced fractional derivative ⁹^-¹⁸^,²³^,²⁴.

In addition, another new definition of local fractional derivative is introduced by P. M. Guzmán et al. ²⁵, and it is called the non-conformable fractional derivative which is considered as a natural extension of the usual derivative of a function a point. The difference between conformable fractional derivative and non-conformable fractional derivative is that the tangent line angle is conserved in the conformable one, while it is not conserved in the sense of nonconformable one ²⁵ (see also ²⁶^,³⁴^,³⁶^,³⁷ for more new related results about this newly proposed definition of non-conformable fractional derivative). The definition of non-conformable fractional derivative has been investigated and applied in various research studies and applications of physics and natural sciences such as the stability analysis, oscillatory character, and boundedness of fractional Liénard-type systems ²⁷^,²⁸^,³³, analysis of the local fractional Drude model ²⁹, Hermite-Hadamard inequalities ³⁰, fractional Laplace transform ³¹, fractional logistic growth models ³², oscillatory character of fractional Emden-Fowler equation ³⁵, asymptotic behavior of fractional nonlinear equations ³⁸, and qualitative behavior of nonlinear differential equations ³⁹.

This paper is organized as follows: In Sec. 2, the main concepts of conformable fractional calculus are presented. Section 3, we proved a conformable version of the conformable second-order Sturm-Picone identity. From this result, we establish the conformable Sturm-Liouville comparison and separation theorems. Section 4, for a conformable Sturm-Liouville problem, the Green function is constructed, and its properties are studied. At the end, we prove the generalized Hyers-Ulam stability of conformable inhomogeneous linear differential equations with homogeneous boundary conditions.

2.Basic definitions and tools

Definition 1. Given a functionf:]0∞)→R. Then, the conformable fractional derivative of order α, ³, is defined by

(Tαf)(t)=limε→0f(t+εt1-α)-f(t)ε, (1)

for all t > 0, 0<α≤1. If f is α-differentiable in some (0,α), α > 0, andlimt→0+(Tαf)(t)exists, then it is defined as

(Tαf)(0)=limt→0+(Tαf)(t). (2)

Theorem 1. ³. If a functionf:]0,∞)→R is α-differentiable att0>0, 0<α≤1, then f is continuous at t ₀ .

Theorem 2. ³. Let0<α≤1, and let f,g be α-differentiable at a point t > 0. Then

Tα(af+bg)=a(Tαf)+b(Tαg), ∀ a,b∈R.
Tα(tp)=ptp-α, ∀p∈R.
Tα(λ)=0,for all constant functionsf(t)=λ.
Tα(fg)=f(Tαg)+g(Tαf).
Tα(f/g)=(g[Tαf]+f[Tαg])/g2.
If, in addition, f is differentiable, then (Tαf)(t)=t1-α(df/dt)(t).

The conformable fractional derivative of certain functions for the above definition is given as:

Tα(1)=0,
Tα(sin(at))=at1-αcos(at),
Tα(cos(at))=-at1-αsin(at),
Tα(eat)=aeat, a∈R.

Definition 2. The (left) conformable derivative starting from a of a given function f:]a,∞)→R of order 0<α≤1, ⁴, is defined by

(Tαaf)(t)=limε→0f(t+ε(t-a)1-α)-f(t)ε, (3)

When α = 0, it is written as (Tαf)(t). If f is α-differentiable in some (a,b), then the following can be defined as:

(Tαaf)(a)=limt→a+(Tαaf)(a), (4)

Theorem 3 (Chain Rule). ⁴. Assume f,g:(a,∞)→R be (left) α-differentiable functions, where 0<α≤1. By letting h(t)=f(g(t)), h(t) is α-differentiable for all t≠a and g(t)≠0, therefore, we have the following:

(Tαah)(t)=(Tαaf)(g(t))⋅(Tαag)(t)⋅(g(t))α-1, (5)

if t = α, then

(Tαah)(a)=limt→a+(Tαaf)(g(t))⋅(Tαag)(t)⋅(g(t))α-1, (6)

Theorem 4 (Rolle’s Theorem) . ³. Let α > 0, α∈(0,1] and f:[a,∞)→ be a given function that satisfies the following:

f is continuous on [a,b].
f is α-differentiable on (a,b).
f(a)=f(b).

Then, there exists c∈(a,b), such that (Tαf)(c)=0.

Corollary 1. Let I⊂[0,∞), α∈(0,1] and f:I→R be a given function that satisfies

f is α differentiable on I.
f(a)=f(b)=0 for certain c∈I.

Then, there exists c∈(a,b), such that (Tαf)(c)=0.

Theorem 5. (Mean Value Theorem). ³. Let α > 0, α∈(0,1] and f:[a,∞)→R be a given function that satisfies

f is continuous in [a,b].
f is α-differentiable on (a,b).

Then, exists c∈(a,b) such that

(Tαf)(c)=f(b)-f(a)bαα-aαα, (7)

Theorem 6. ⁵. Let α > 0, α∈(0,1] and f:[a,∞)→R be a given function that satisfies

f is continuous in [a,b].
f is α-differentiable on (a,b).

If (Tαf)(c)=0 for all t∈(a,b), then f is a constant on (a,b).

Corollary 7. [5]. Let α > 0, α∈(0,1] and F,G:[a,∞)→R be functions such that (TαF)(t)=(TαG)(t) for all t∈(a,b). Then, there exists a constant C such that

F(t)=G(t)+C, (8)

The following definition is the α-fractional integral of a function f starting from a≥0:

Definition 3.

Iαa(f)(t)=∫atf(x)x1-α⋅dx,

where the integral is the usual Riemann improper integral, and α∈(01] ².

Theorem 8. TαaIαa(f)(t)=f(t), for t≥a, where f is any continuous function in the domain of Iα.

Lemma 9. Let f:(a,b)→R be differentiable and α∈(0,1]. Then, for all α > 0,, we have ³,

IαaTαa(f)(t)=f(t)-f(a), (9)

Finally, we give the definition of non-conformable a-Wronskian, which is necessary in the next section.

Definition 4. Let x and 𝑦 be given conformable a-differentiable functions on [a,b] with a≥0 and α∈(0,1]. We set the following:

Wαx,yt=*20cxtytTαxtTαyt. (10)

3.Sturm’s theorems

In this section, we consider the scalar fractional differential equation of order α + α as follows:

TαTαx(t)+p(t)Tαx(t)+q(t)x(t)=0, (11)

with continuous functions p and q, and α∈(0,1]. Traditionally, from ¹⁹, two functions x and y that are continuous on [a,b] for some 0≤a<b, will be called linearly dependent if there exist c₁, c2∈R such that |c1|+|c1|>0 and c1x(t)+c2y(t)≡0 for all t∈[a,b]. In the other case, they are linearly independent.

Remark 1. We can write

Wα(x,y)(t)=e-∫t0tp(x)x1-αdxWα(x,y)(t0), (12)

for two solutions x and y of ⁵ and some t0∈(a,b). In fact, we apply the operator Tα on Wα(x,y)(t) to obtain

Tα(Wα(x,y)(t))=Tα(x(t)Tαy(t)-y(t)Tαx(t)=Tαx(t)Tαy(t)+x(t)TαTαy(t)-Tαy(t)Tαx(t)-y(t)TαTαx(t).

However, x and y satisfies (11). Hence, we have:

TαTαx(t)=-p(t)Tαx(t)-q(t)x(t),

and

TαTαy(t)=-p(t)Tαy(t)-q(t)y(t).

Therefore, we get

Tα(Wα(x,y)(t))=-(x(t)Tαy(t)-y(t)Tαx(t))p(t)=-(Wα(x,y)(t))p(t).

Thus

Tα(Wα(x,y)(t))Wα(x,y)(t)=-p(t).

Consequently, we have

Wα(x,y)(t)=e-∫t0t(p(x)/1-α)dxWα(x,y)(t0).

This completes the proof.

Similar to the classical case, by using the above formula, we can immediately obtain the following equivalent condition of linear independence:

Theorem 10. Two solutions x and y of (11) defined on [a,b] for some 0≤a<b are linearly independent if and only if Wα(x,y)(t)≠0 for all t∈[a,b].

Now, we propose a conformable version of three classical results, the Sturm-Picone identity, Sturm’s comparison, and separation theorems of order a + a ²⁰.

Let us now introduce the conformable self-adjoint Sturm-Liouville equation as follows:

-Tα(p1(t)Tαx(t))+p0(t)x(t)=0, (13)

-Tα(p1(t)Tαx(t))+p0(t)x(t)=0, (14)

where p₀, p₁, q₀, q₁, Tα, p₁Tαq1 are continuous on some closed interval I⊂[0,+∞), p₁ > 0, q₁ > 0 on I and α∈(0,1].

Theorem 11 (Conformable Picone Identity). If x(t), y(t) and p1(t)Tαx(t), q1(t)Tαy(t) are α-differentiable for t∈I and y(t)≠0 in I, then we obtain

Tαx(t)y(x)p1(t)y(t)Tαx(t)-q1(t)x(t)Tαy(t)=x(t)Tα(p1(t)Tαx(t))-(x(t))2y(t)Tα(q1(t)Tαy(t))+(p1(t)-q1(t))(Tαx(t))2+q1(t)×Tαx(t)-x(t)y(t)Tαy(t)2. (15)

Proof. This arises from the straightforward α-differentiation.

Theorem 12 (Conformable Sturm’s Comparison Theorem). Let 0? a < b be two consecutive zeros of a nontrivial solution x(t) of (3.3). Suppose that

0<q1(t)≤p1(t),

and

q0(t)≤p0(t).

for all t∈[a,b]. Then, every solution y(t) of (14) has at least one zero in the closed interval [a,b].

Proof. If x(t) and y(t) are solutions of (13) and (14), respectively, and y(t)≠0 for all t∈[a,b], then the conformable Picone identity (15) yields on substitution of (13) and (14) as follows:

Tαx(t)y(t)p1(t)y(t)Tαx(t)-q1(t)x(t)Tαy(t)=(p0(t)-q0(t))(x(t))\dos+(p1(t)-q1(t))(Tαx(t))2+q1(t)Tαx(t)-x(t)y(t)Tαy(t)2.

Integrating over [a,b]; therefore, we have (see Lemma 9),

∫ab((p0(t)-q0(t))(x(t))2+(p1(t)-q1(t))(Tαx(t))2+q1(t)Tαx(t)-x(t)y(t)Tαy(t)2)1t1-αdt=x(t)y(t)[p1(t)y(t)Tαx(t)-q1(t)x(t)Tαy(t)t=at=b. (16)

The right-hand side of (16) evaluates to zero by assuming x(a)=x(b)=0, and y(a)≠0, y(b)≠0. Since q1(t)>0 in [a,b], the third term of the integrand is nonnegative over [a,b]. Hence, we must have either

Tαx(t)-(x(t)/y(t))Tαy(t)≡0 in [a,b]

∫ab([p0t-q0t]xt2+[p1t-q1t](Tαx(t))2)×(1/t1-α)dt<0.

However, case (ii) gives an immediate contradiction since p0(t)-q0(t)≥0 and p1(t)-q1(t)≥0 by assumption. In Case (i), we are also led to a contradiction since (i) implies

y(t)Tαx(t)-x(t)Tαy(t)(y(t))2=Tαx(t)y(t)≡0,

or (t)≡ky(t) for all t∈[a,b], for some k≠0, but y(a)=y(b)=0 which is a contrary to our assumption.

Theorem 13 (Conformable Sturm’s Separation Theorem) . Let 0≤a<b be two consecutive zeros of a nontrivial solution x(t) of (13). Let y(t) be any other solution of (13) which is linearly independent of x(t). Then, y(t) has exactly one zero of the intervall (a,b). In other words, the zeros of any two linearly independent solutions of (13) are interlaced.

Proof. On the contrary, suppose that y(t)≠0 for all t∈(a,b). Since x(t) and y(t) are linearly independent, it follows that y(a)≠0; otherwise, we would have

Wα(x,y)(a)=*20cx(a)y(a)Tαx(t)Tαy(t)=0,

which implies that the conformable Wronskian, Wα(x,y)(t), is zero for all t and that x(t) and y(t) are linearly dependent. For the same reason, we know that y(b)≠0, but when q1(t)≡p1(t) and q0(t)≡p0(t), (16) becomes

∫abp1(t)Tαx(t)-x(t)y(t)Tαy(t)21t1-αdt=x(t)y(t)p1(t)(y(t)Tαx(t)-x(t)Tαy(t))t=at=b.

Since y(a)≠0 and y(b)≠0, the right-hand side evaluates to zero. Since p1(t)>0 in [a,b], it follows that Tαx(t)-(x(t)/y(t))Tαy(t)≡0, or

Wα(x,y)(t)=y(t)Tαx(t)-x(t)Tαy(t)≡0,

for all t∈(a,b). Hence, x(t) and y(t) are linearly dependent on (a,b) which is a contrary to our assumption.

Remark 2.

Conformable Sturm’s Comparison Theorem guarantees the existence of at least one zero.
The assumption cannot be dropped. Consider the equation on ecuacion, , and and let x(t) and y(t) be their non-trivial solutions, respectively. Between any two zeros of x(t), y(t) does not admit a zero.
Consider the equation on, , and, and let and be their non-trivial solutions, respectively. However, there is no zero of x(t) between two consecutive zeros of y(t).

Remark 3. An important application of Sturm’s Comparison Theorem is to provide a good understanding of the zero set on non-trivial solutions of Conformable Bessel’s Equation. The Conformable Bessel’s Equation is given by

t2αTαTαy(t)+αtαTαy(t)+α2(t2α-p2)y(t)=0, (17)

where α∈(0,1] and p≥0. Clearly, if a = 0, the above equation is just the classical Bessel Equation, ¹⁹. For more information about the conformable Bessel’s function in the solution of wave equation, we refer to ²¹.

For t > 0, making a change variable y=v/tα/2, the (17) transforms into

TαTαy(t)+α21+1-4p24t2αv(t)=0. (18)

(To obtain the above equation, we start differentiating the equation tα/2y=v).

Case 1: p>1/2. In this case, compare (18) with

TαTαy(t)+α2y(t)=0,

which has a solution sin(tα) with zeros at t=(nπ)1/α, n∈N. Therefore, a solution of (18) has at least one zero on each of the open interval ([{n-1}π]1α,(nπ)1α], n∈N.

Case 1: 0<p<1/2. In this case, compare (18) with

TαTαy(t)+α2y(t)=0,

and conclude that between any two consecutives zeros, a and b of v(t), there exists one zero of sin(tα). Thus, we have a<(nπ)1/α<b for some n∈N.

4.The study of conformable Green’s Functions

4.1.Conformable Green’s Functions

In this section, we consider the conformable Sturm- Liouville system

Tα(p(t)Tαx(t))+(λρ(t)-q(t))x(t)=0(19a)a1x(a)+a2Tαx(a)=0(19b)b1x(a)+b2Tαx(a)=0(19c)}, (19)

|a1|+|a2|≠0, |b1|+|b2|≠0,

with continuous functions p(t), q(t) and ρ(t) on [a,b] for some 0≤a<b, such that ρ(t)≥0 and p(t)≥0 for all t∈[a,b] and α∈(0,1].

Definition 5. Let Q denote the square Q=a,b×[a,b] for some 0≤a<b, in the t∈ -plane. A function Gα(t,ε) defined in Q is called conformable Green’s Function of Sturm-Liouville system (19), if it has the following properties:

The function Gα(t,ε) is continuous in Q.
Let ε∈(a,b) be fixed. Then, Gα(t,ε) has conformable partial derivatives of left and right with respect to variable t, for t=ε, and it is verified as follows:
∂α∂tαGα(ε+,ε)-∂α∂tαGα(ε-,ε)=-1p(ε).
Let ε∈[a,b] be fixed. Then, Gα(t,ε) has continuous conformable partial derivatives of first and second order with respect to variable t, if t≠ε, and it is verified as follows:
∂α∂tα(p(t)TαGα(t,ε))+(λρ(t)-q(t))Gα(t,ε)=0.
Let ε∈(a,b) be fixed. Then, Gα(t,ε) satisfies the boundary conditions (19b) and (19c).

Theorem 14. Let x1/(t) and x2 (t) be two solutions of (19a) that verify condition (19b). Then, x1(t) and x2(t) are linearly dependent.

Proof. Since |a1|+|a2|≠0, it follows from

a1x1(a)+a2Tαx1(a)=0,a1x1(a)+a2Tαx1(a)=0,

that

Wα(x,y)(a)=|cx1(a)x2(a)Tαx1(a)Tαx2(a)|=0.

Therefore, x₁(t) and x₂(t) are linearly dependent.

Theorem 15. Let x₁(t) and x₂(t) be two solutions of (19a) that verify condition (19c). Then, x₁(t) and x₂(t) are linearly dependent.

Proof. It is analogous to the proof of the above theorem.

Theorem 16. System (19) has no Green’s Function if λ is an eigenvalue.

Proof. Let x₁(t) be an eigenfunction of system (19). Let x₂(t) be a solution of (19a) linearly independent of x₁(t). From Theorems 14 and 15, it turns out that x₂(t) does not verify the conditions (19b) and (19c).

According to the condition (iii) of Gα(t,ε), the said function is a solution of (19a) in the intervals a≤t<ε and ε<t≤b, so it has the following form:

Gα(t,ε)=cA1(ε)x1(t)+A2(ε)x2(t)a≤t<εB1(ε)x1(t)+B2(ε)x2(t)ε<t≤b.

Let us now express that Gα(t,ε) meets the condition (iv)

a1(A1(ε)x1(a)+A2(ε)x2(a))+a2(A1(ε)Tαx1(a)+A2(ε)Tαx2(a))=0,b1(B1(ε)x1(b)+B2(ε)x2(b))+b2(B1(ε)Tαx1(b)+B2(ε)Tαx2(b))=0.

Since x₁(t) meets both conditions (19b) and (19c), the above equalities are reduced to

A2(ε)(a1x2(a)+a2Tαx2(a))=0,B2(ε)(b1x2(b)+b2Tαx2(b))=0.

On the contrary, we have

a1x2(a)+a2Tαx2(a)≠0,b1x2(b)+b2Tαx2(b)≠0.

so that

A2(ε)=0, a≤t<ε,B2(ε)=0, ε<t≤b.

From here, we have

Gα(t,ε)=cA1(ε)x1(t)a≤t<εB1(ε)x1(t)ε<t≤b.

Since Gα(t,ε) is a continuous function, we obtain

limt→ε-Gα(t,ε)=A1(ε)x1(ε)=limt→ε+Gα(t,ε)=B1(ε)x1(ε),

so that

A1(ε)=B1(ε), a<ε<b.

From here, it follows that

∂α∂tαGα(ε+,ε)-∂α∂tαGα(ε-,ε)=0,

which contradicts condition (ii).

Theorem 17. System (19) has one, and only one, Green’s Function if λ is not an eigenvalue.

Proof. Let x₁(t) and x₂(t) two solutions of (19) such that

x1(a)=a2, Tαx1(a)=-a1,x2(b)=b2, Tαx2(b)=-b1.

Since |a1|+|a2|≠0, |b1|+|b2|≠0, x₁(t) and x₂(t) are not null, they are also satisfying conditions (19b) and (19c), respectively.

These solutions are linearly independent, since otherwise it would be

x1(t)=μx2(t), μ≠0.

Therefore, we have

b1x1(b)+b2Tαx1(b)=μ[b1x2b+b2Tαx2b]=0.

As a result, x₁(t) would comply with (19b) and (19c). This is not possible since x₁(t) is not an eigenfunction.

The reasoning as in the proof of Theorem 16, we have to

Gα(t,ε)=A1(ε)x1(t)+A2(ε)x2(t)a≤t<εB1(ε)x1(t)+B2(ε)x2(t)ε<t≤b.

Expressing that Gα(t,ε) meets the condition (iv), and it turns out that

a1(A1(ε)x1(a)+A2(ε)x2(a))+a2(A1(ε)Tαx1(a)+A2(ε)Tαx2(a))=0,b1(B1(ε)x1(b)+B2(ε)x2(b))+b2(B1(ε)Tαx1(b)+B2(ε)Tαx2(b))=0,

that is reduced to

A2(ε)(a1x2(a)+a2Tαx2(a))=0,B1(ε)(b1x1(b)+b2Tαx1(b))=0,

from where it follows, remembering that x₁(t) and x₂(t) are not eigenfunctions and, therefore, a1x2(a)+a2Tαx2(a)≠0, b1x1(b)+b2Tαx1(b)≠0,

A2(ε)=0B1(ε)=0 a<ε<b.

Now, by applying conditions (i) and (ii), it turns out that

A1(ε)x1(ε)+B2(ε)x2(ε)=0,A1(ε)Tαx1(ε)+B2(ε)Tαx2(ε)=1p(ε),

which allows us to calculate the following:

A1(ε)=-x2(ε)pε[x1εTαx2ε-x2εTαx1ε],B2(ε)=-x1(ε)pε[x1εTαx2ε-x2εTαx1ε].

Note that x1(ε)Tαx2(ε)-x2(ε)Tαx1(ε) is nonzero since it is conformable Wronskian of two linearly independent solutions of (19).

Given the following:

Tα(p(t)Tαx1(t))+(λρ(t)-q(t))x1(t)=0,Tα(p(t)Tαx2(t))+(λρ(t)-q(t))x2(t)=0.

By multiplying the first equation by x₂(t), the second by x₁(t), and subtracting, we have

x2(t)Tα(p(t)Tαx1(t))-x1(t)Tα(p(t)Tαx2(t))=0

that can be written in the form

p(t)(x2(t)Tαx1(t))-x1(t)Tαx2(t))=0.

So, p(ε)(x2(ε)Tαx1(ε)-x1(ε)Tαx2(ε)) is a constant K that does not depend on ε.

Hence, we have

Gα(t,ε)=1Kx1(t)x2(ε)a≤t<ε1Kx1(ε)x2(t)ε<t≤b

The conformable Green’s Function Gα(t,ε) has the properties (i) - (iv). The uniqueness of this function is easily deduced from the method that we have followed to determine Gα(t,ε).

Ejemple 1. Consider the system

TαTαx(t)+x(t)=0t∈[0,(απ)1α]x(0)+Tαx(0)=0x((απ)1/α)=0

for some α∈(0,1], we will find the corresponding conformable Green’s Function. In this case p(t) = 1, q(t)= -1, λ = 0, ρ(t) is any positive continuous function in [0,(απ)(1/α)], α₁ = 1, α₂ = 1, b₁ = 1, b₂ = 0.

The general solution of TαTαx(t)+x(t)=0 is

xt=A costαα+B sintαα.

Then, we have

x(0)+Tαx(0)=A+B=0,x((απ)1/α)=-A=0.

From here A = 0, B = 0, so there was the conformable Green’s Function of the given system.

The solutions of TαTαx(t)+x(t)=0; x1(t)=costα/α+sintα/α, x2(t)=sintα/α satisfy the conditions x(0)+Tαx(0)=0,x((απ)(1/α))=0. The conformable Green’s Function has the form

Gα(t,ε)=1Kx2(ε)x1(t)0≤t<ε1Kx1(ε)x2(t)ε<t≤(απ)1/α

so that

K=p(ε)(x2(ε)Tαx1(ε)-x1(ε)Tαx2(ε))=-sin⁡εαα+cos⁡εααsin⁡εαα--cos⁡εαα+sin⁡εααcos⁡εαα=-1.

Therefore, we obtain

Gα(t,ε)={-sin⁡εααcos⁡tαα+sin⁡tαα0≤t<ε-cos⁡εαα+sin⁡εαα sin⁡tααε<t≤(απ)1/α

4.2.The applicability of conformable Green’s function

In this section, we consider the system

Tα(p(t)Tαx(t))-q(t)x(t)=0(20a)a1x(a)+a2(x)Tαx(a)=0(20b)b1x(a)+b2(x)Tαx(b)=0(20c) (20)

obtained from (19) for λ = 0. We now propose to solve the inhomogeneous system

Tα(p(t)Tαx(t))-q(t)x(t)=-f(t)a1x(a)+a2(x)Tαx(a)=0b1x(a)+b2(x)Tαx(b)=0 (21)

where f(t) is a real continuous function in the interval [a,b] for some 0≤a<b.

Theorem 18. If the homogeneous system (20) has its only solution as the identically null function, then (21) has only one solution, which is given by

x(t)=∫abGα(t,ε)f(ε)1ε1-αdε,

where Gα(t,ε) is the conformable Green’s Function of (20).

Proof. That homogeneous system (20) has its unique solution as the identically null function which is equivalent to saying that λ = 0 is not an eigenvalue of (19); therefore, there is the conformable Green’s Function of (20).

Let x₁(t) and x₂(t) be two linearly independent solutions of (20a) that verify (20b) and (20c), respectively. Let us apply the conformable version of the method of variation of the parameters to solve (20a). Then, we have

x(t)=A(t)x1(t)+B(t)x2(t)Tαp(t)x1(t)TαA(t)+x2(t)TαB(t)+A(t)Tαx1(t)+B(t)Tαx2(t)-Q(t)A(t)x1(t)+B(t)x2(t)=-f(t),

that is to say

A(t)Tαp(t)Tαx1(t)-A(t)q(t)x1(t)[+B(t)Tα(p(t)Tαx2(t)-B(t)q(t)x2(t)+p(t)TαA(t)Tαx1(t)+TαB(t)Tαx2(t)+Tαp(t)x1(t)TαA(t)+x2(t)TαB(t)=-f(t),

that is

p(t)TαA(t)Tαx1(t)+TαB(t)Tαx2(t)+Tαpt[x1tTαAt+x2tTαBt]=-f(t).

We make

x1(t)TαA(t)+x2(t)TαB(t)=0,

and we have

p(t)TαA(t)Tαx1(t)+TαB(t)Tαx2(t)=-f(t)

so that

TαA(t)=-x2(t)f(t)p(t)x2(t)Tαx1(t)+x1(t)Tαx2(t),TαB(t)=-x1(t)f(t)p(t)x2(t)Tαx1(t)+x1(t)Tαx2(t).

We know, from the proof of Theorem 17, that p(t)(x2(t)Tαx1(t)+x1(t)Tαx2(t)) is a constant, and it is equal to K. On the contrary, we have

a1x(a)+a2Tαx(a)=a1A(a)x1(a)+B(a)x2(a)+a2(x1(a)TαA(a)+x2(a)TαB(a)+A(a)Tαx1(a)+B(a)Tαx2(a))=A(a)(a1x1(a)+a2Tαx1(a))+B(a)(a1x2(a)+a2Tαx2(a))=B(a)(a1x2(a)+a2Tαx2(a))=0

and since x₂(t) is not an eigenfunction of (20) it turns out that

a1x2(a)+a2Tαx2(a)≠0,

so that B(a) = 0.

By writing now the following:

b1x(b)+bTαx(a)=0.

Similarly, we obtain A(b) = 0.

So, we have

A(t)=∫atx2(ε)Kf(ε)1ε1-αdε+C1,

and since A(b) = 0, we have to

A(t)=-∫atx2(ε)Kf(ε)1ε1-αdε+∫abx2(ε)Kf(ε)1ε1-αdε=∫tbx2(ε)Kf(ε)1ε1-αdε.

Analogously

B(t)=-∫atx1(ε)Kf(ε)1ε1-αdε.

Thus, we obtain

x(t)=A(t)x1(t)+B(t)x2(t)=∫tbx1(t)X2(ε)Kf(ε)1ε1-αdε+∫atX1(ε)x2(t)Kf(ε)1ε1-αdε=∫abG3α(t,ε)f(ε)1ε1-αdε,

where we have the following

Gα(t,ε)=1Kx1(t)x2(ε)a≤t<ε1Kx1(ε)x2(t)ε≤t<b.

which is the Green’s Function.

Example 2. By using the Green’s Function, we want to solve the following system

TαTαx(t)+x(t)=etα/αt∈[0,(απ)1α]x(0)=0Tαx((απ)1/α)=0.

First, we find the conformable Green’s Function of the homogeneous system.

We have following:

x(t)=Acos⁡tαα+Bsin⁡tαα X(0)=0=A Tαx((απ)1/α)=0=B.

Therefore, the conformable Green’s Function exists. This function can be written as

Gα(t,ε)={cos⁡εαα sin⁡tαα0≤t<εsin⁡εααcos⁡tααε<t≤(απ)1/α.

Therefore, our intended solution can be written as follows:

x(t)=-∫0απ1αGα(t,ε)eεαα1ε1-αdε=-∫0tsin⁡εααcos⁡tααeεαα1ε1-αdε-∫tαπ1αcos⁡εααsin⁡tααeεαα(απ)1αdε=-12cos⁡tααeεααsin⁡εαα-cos⁡εαα|ε=0ε=t-12sin⁡tααeεααsin⁡εαα-cos⁡εαα|ε=tε=(απ)1α=-12cos⁡tααeεααsin⁡tαα-cos⁡tαα+1-12sin⁡tααeπ-etααsin⁡tαα-cos⁡tαα eπ-sin⁡tααcos⁡tαα+12-12cos⁡tαα-12eπsin⁡tαα.

Finally, we investigate the generalized Hyers-Ulam stability of the conformable linear inhomogeneous differential equation of order α + α (21) in the class of continuously twice α -differentiable functions.

Theorem 19. Let p,q,f:[a,b]→R be continuous functions and let p be α-differentiable function on [a,b]. Assume that the conformable homogeneous differential equation (20) has its only solution as the identically null function. If a twice continuously α-differentiable function x:[a,b]→R satisfies the inequality

|Tα(p(t)Tαx(t))-q(t)x(t)+f(t)|≤φ(t), (22)

for all t∈[a,b], where φ:a,b→[0,∞) is given that such of the following integrals exists, then there exists a solution x0:[a,b]→R of (21) such that

|x(t)-x0(t)|≤1|K||x1(t)|∫bt|x2(ε)|φ(ε)1ε1-αdε+|x2(t)|∫at|x1(ε)|φ(ε)1ε1-αdε, (23)

|x(t)-x0(t)|≤1|K||x1(t)|∫bt|x2(ε)|φ(ε)1ε1-αdε+|x2(t)|∫at|x1(ε)|φ(ε)1ε1-αdε,

where K is a nonzero constant and x₁(t) and x₂(t) are two linearly independent solutions of (20a) that verify (20b) and (20c), respectively (see Theorem 18).

Proof. If we define a continuous function s:[a,b]→R by

s(t)=Tα(p(t)Tαx(t)-q(t)x(t)), (24)

for all t∈[a,b], then it follows (22) that

|s(t)+f(t)|≤φ(t), (25)

for all t∈[a,b]. In view of Theorem 18 and (24), we have

x(t)=-∫abGα(t,ε)s(ε)1ε1-αdε=-∫tbx1(t)x2(ε)Ks(ε)1ε1-αdε-∫atx1(ε)x2(t)Ks(ε)1ε1-αdε (26)

where K is a nonzero constant because x₁(t) and x₂(t) are two linearly independent solutions of (20a) that verify (20b) and (20c), respectively (see Theorem 18). We now define a function x0:[a,b]→R by

x0(t)=∫tbx1(t)x2(ε)Kf(ε)1ε1-αdε+∫atx1(ε)x2(t)Kf(ε)1ε1-αdε, (27)

for all t∈[a,b]. According to Theorem 18, it is obvious that x₀ is a solution of (21). Moreover, it follows from (25), (26) and (27) that

|x(t)-x0(t)|≤|-∫tbx1(t)x2(ε)K(s(ε)+f(ε))1ε1-αdε-∫atx1(ε)x2(t)K(s(ε)+f(ε))1ε1-αdε|≤1|K||x1(t)|∫ab|x2(ε)|φ(ε)1ε1-αdε+|x2(t)|∫at|x1(ε)|φ(ε)1ε1-αdε

for all t∈[a,b].

Remark 4. Theorem 19 reduces to ²² (Theorem 3.2) in the case α = 0 and using the Green’s Function.

5.Conclusion

In this research paper, we have proposed some results referring to the conformable boundary value problems. The conformable Sturm-Picone identity of order α + α has been proven, and its Sturm’s theorems of comparison and separation have been successfully established. As in the classical case, an important application of the Sturm’s comparison theorem is to provide a clear understanding of the zero set of non-trivial solutions of the conformable Bessel’s equation. For a conformable Sturm-Liouville system, we have defined the Green’s function and established its properties. The conformable Green’s function is applied to construct the solution of the inhomogeneous problem of Sturm-Liouville, whose associated homogeneous problem has its only solution as the identically null function. Finally, we have proved the generalized Hyers-Ulam stability of the conformable linear inhomogeneous differential equation of order α + α (21) in the class of continuously twice α-differentiable functions.

Conflict of interest

All authors declare no conflicts of interest in this research paper.

Acknowledgments

All authors would like to express their very great appreciation to all referees and editorial board members for their helpful suggestions and valuable comments.

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Received: November 12, 2020; Accepted: January 11, 2021

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Revista mexicana de física

versión impresa ISSN 0035-001X

Rev. mex. fis. vol.67 no.3 México may./jun. 2021 Epub 21-Feb-2022

https://doi.org/10.31349/revmexfis.67.47