On Some Properties of the New Generalized Fractional Derivative with Non-Singular Kernel

)is paper presents some new formulas and properties of the generalized fractional derivative with non-singular kernel that covers various types of fractional derivatives such as the Caputo–Fabrizio fractional derivative, the Atangana–Baleanu fractional derivative, and the weighted Atangana–Baleanu fractional derivative.)ese new properties extendmany recent results existing in the literature. Furthermore, the paper proposes some interesting inequalities that estimate the generalized fractional derivatives of some specific functions. )ese inequalities can be used to construct Lyapunov functions with the aim to study the global asymptotic stability of several fractional-order systems arising from diverse fields of science and engineering.


Introduction
In the literature, there exist manifold types of fractional derivatives which are used to solve several mathematical and engineering problems as well as to model the dynamics of many systems existing in various fields of science such as mechanics, chemistry, finance, ecology, biology, and control theory. For instance, Caputo and Fabrizio [1] proposed a fractional derivative with non-singular kernel to describe the material heterogeneities and the fluctuations of different scales, which cannot be well described by classical local theories or by fractional models with singular kernel. An extension of [1] was proposed by Atangana and Baleanu [2] by using Mittag-Lefler function with one parameter. Due to the importance of weighted fractional derivatives to solve several types of integral equations with elegant ways, Al-Refai [3] introduced the weighted Atangana-Baleanu fractional operators and he studied their properties. A generalized version of all previous fractional derivative operators with non-singular kernel was recently proposed in [4]. e objective of this study is to establish some properties and formulas of the new generalized fractional derivative introduced in [4] in order to extend several results presented in recent works. To achieve this goal, the remainder of this article is outlined as follows. e next section deals with preliminaries and fractional derivatives of some specific functions. e estimates of the generalized fractional derivatives of these specific functions can be applied to find Lyapunov candidate functions for demonstrating the global stability of many fractional-order systems. Section 3 is devoted to the new formulas and properties of the generalized fractional derivative with nonsingular kernel. e paper ends with a conclusion in Section 4.

Preliminaries and Fractional Derivatives of Some Specific Functions
In this section, we first recall the definition and special cases of the new generalized fractional derivative with non-singular kernel. After, we present new properties for this fractional derivative that can be used to prove the global dynamics of several fractional-order systems.
Definition 1 (see [4]). Let α ∈ [0, 1), β, c > 0, and f ∈ H 1 (a, b). e new generalized fractional derivative of order α of Caputo sense of the function f(t) with respect to the weight function w(t) is defined as follows: where e importance of the fractional derivative given in the above definition is the generalization of most cases existing in the literature. ese particular cases can be summarized in the following remark.

Remark 1.
(i) If w(t) � 1 and β � c � 1, then (1) is reduced to the Caputo-Fabrizio fractional derivative [1] given by (1) is reduced to the Atangana-Baleanu fractional derivative [2] given by (1) is reduced to the weighted Atangana-Baleanu fractional derivative [3] given by Now, we establish new properties for the generalized fractional derivative. We begin with the following result.

Theorem 1. Let f be a continuous function and u be a continuously differentiable function. For any constant c, the new generalized fractional derivative of the function F defined by
satisfies the following property: where Moreover, we have the following inequalities: (ii) If f is a decreasing function, then Proof. By using Definition 1, we have Let en, and v(t) � 0. Integrating by parts the last integral, we find

Corollary 1. Let u(t) ∈ IR be a continuously differentiable function. en, for any time
(17) Proof. Applying (i) of eorem 1 to the function f(x) � 2x, we get is completes the proof.
□ Remark 2. Corollary 1 extends the result presented in Lemma 3.1 of [5] for the new generalized fractional derivative. In fact, it suffices to take c � β � α in inequality (17). Now, we extend the recent result presented in Lemma 3.2 of [5] by proposing the following corollary.

Corollary 2.
Let u(t) ∈ IR + be a continuously differentiable function and u * > 0. en, for any time t ≥ t 0 , we have Proof. e application of eorem 1 (ii) to the function f(x) � 1/x leads to the following: (20) e proof of Corollary 2 is completed.

New Formulas and Properties
For simplicity, we denote C D α,β,β a,t,1 by D α,β a,w . According to [4], we have the following definition.
Definition 2 (see [4]). e generalized fractional integral operator corresponding to D α,β a,w is defined by where RL I β a,w is the standard weighted Riemann-Liouville fractional integral of order β defined by e Atangana-Baleanu fractional integral operator is a special case of (21), and it suffices to take w(t) � 1 and β � α.

Lemma 1.
e fractional derivative D α,β a,w can be expressed as follows: is series converges locally and uniformly in t for any a, α, β, w, and f satisfying the conditions from Definition 1. Proof.
e Mittag-Leffler function E α (t) is a sum of an entire series. is series converges locally and uniformly in the whole complex plane. Hence, we can rewrite the fractional derivative D α,β a,w as follows: Mathematical Problems in Engineering is completes the proof. By applying eorem 3 for w(t) � 1, we get the following important result that extends the Newton-Leibniz formula presented in [6,7].

Corollary 3.
e generalized fractional integral and the generalized fractional derivative satisfy the following Newton-Leibniz formula: f(a). (31)

Conclusion
In many fields of science like mathematical biology, the method of constructing Lyapunov functions is often based on quadratic and Volterra-type functions. So, the first aim of this work was to estimate the generalized fractional derivatives of these specific functions. e obtained results extend many elementary lemmas existing in the recent literature for other types of fractional derivatives. Furthermore, the second purpose of this work was to establish a new formula for the generalized fractional derivative in the form of a series of weighted Riemann-Liouville fractional integrals. By means of this formula, various properties of the generalized fractional derivatives and integrals operators have been carefully established. Moreover, the Newton-Leibniz formula has been rigorously extended.
e results presented in this study form a fundamental basis for extending the classical Lyapunov theorems [8][9][10] and LaSalle's invariance principle [11] to the case of the new generalized fractional derivative. is issue will be the first direction of our future works.

Data Availability
e data used to support the findings of this study are available from the corresponding author upon request.

Conflicts of Interest
e author declares that he has no conflicts of interest.