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Further results on the asymptotic stability of Riemann–Liouville fractional neutral systems with variable delays

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Abstract

In this paper, the investigation of the asymptotic stability of Riemann–Liouville fractional neutral systems with variable delays has been presented. The advantage of the Lyapunov functional was used to achieve the desired results. The stability criteria obtained for zero solution of the system were formulated as linear matrix inequalities (LMIs) which can be easily solved. The advantage of the considered method is that the integer-order derivatives of the Lyapunov functionals can be directly calculated. Finally, three numerical examples have been evaluated to illustrate that the proposed method is flexible and efficient in terms of computation and to demonstrate the feasibility of established assumptions by MATLAB-Simulink.

Introduction

Fractional calculus and fractional differential systems have been of considerable interest for the past few decades. It has been proved that fractional-order calculus is more adequate and general to describe real world problems than the integer calculus. Therefore, not only mathematicians have currently had a robust interest in the fractional calculus. At the same time, it is seen that fractional systems without or with time-varying delays often occur in many scientific areas such as engineering techniques fields, physics, polymer rheology, regular variation in thermodynamics, biophysics, blood flow phenomena, capacitor theory, electrical circuits, signal processing, biology, control theory, etc. (see [1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28] and the references therein). There are some studies in the literature including recent developments in the field of the fractional calculus as well as its applications such as the model of spring pendulum in fractional sense [2, 4, 11].

On the other hand, the interest in stability analysis of various fractional neutral differential systems has been growing rapidly due to their successful applications in widespread fields of science and engineering [19, 22]. In this direction, the stability issue for considered systems is one of the important problems in case of theoretical and practical applications. It is clear that the analysis on the stability of fractional-order systems has a more complex structure than that of classical differential equations due to the fractional derivatives that are nonlocal and have weakly singular kernels [5, 14].

It is also known that fractional neutral systems have a more general class than those of the delayed type. The stability of neutral systems proves to be a more complex question because the system includes the derivative of the retarded state. When the related literature is searched, especially in the past few years, increased attention has been devoted to the problem of delay dependent or independent stability via different approaches for fractional neutral systems. But until now, only a few studies have been published for investigation of the stability of fractional neutral systems. However, there are many studies on the stability of neutral systems in differential equations/systems (see [29,30,31,32,33] and the references therein). It is seen that the stability method in most of the studies related to the stability of the systems in the control theory is based on LMI and the classical Lyapunov stability theory such as in [9, 13,14,15,16,17,18,19,20, 25, 34,35,36,37,38]. In this study, the technique of the proof involves some basic inequalities, LMIs, and Lyapunov functional method.

Motivated by the above discussions, in this paper we deal with the asymptotic stability of Riemann–Liouville fractional neutral systems. Compared to integer-order neutral systems with variable delays, the research on the stability of fractional-order neutral systems is still at the stage of exploiting and developing. The main purpose and contribution of this study are listed as follows:

  1. (i)

    In general, there are a few practical algebraic criteria on stability of fractional-order delayed systems in the current literature. The main reason for this fact is that it is very difficult to calculate the fractional-order derivatives of Lyapunov functionals [14, 16, 19, 28]. The advantage of our method is that the integer-order derivatives of the Lyapunov functionals can be directly calculated. Therefore, we do not need to calculate fractional-order derivative of the Lyapunov functional. The obtained stability criteria are defined as LMIs, which are also convenient and feasible to test the asymptotic stability of the addressed fractional neutral systems;

  2. (ii)

    The considered system includes state variable delays, fractional-order derivatives of the states, and variable delays in fractional-order derivatives of states. We have taken into account the effect of these components on the stability of a neutral system simultaneously. The presented results contribute to the Riemann–Liouville fractional-order neutral systems. Also, we give three examples with numerical simulations to illustrate the effectiveness of theoretical results;

  3. (iii)

    Compared to the existing results concerning integer-order neutral systems [30,31,32,33] and fractional-order neutral systems [13, 16, 20] with variable delays, the results of this paper are more general and less conservative. We think that this study will contribute to the related literature, and it may be useful for researchers working on the qualitative behavior of solutions.

The rest of this paper is organized as follows: The problem formulation and some needed assumptions are presented in Sect. 2. The main results of the study, that is, sufficient conditions for asymptotic stability and some assumptions throughout the study and synthesis of the system under consideration, are included in Sect. 3. In Sect. 4, three numerical examples with simulations are shown to illustrate the effectiveness of the solution of the proposed fractional equation system, and the article is finalized with Sect. 5.

Throughout this work, the following notations will be used. \(\Re^{n}\) denotes the n-dimensional Euclidean space; \(\Re^{n \times n}\) is the set of all \(n \times n\) real matrices; \(\Vert \cdot \Vert \) denotes the Euclidean norm for vectors; let \(C = C([ - h, 0], R^{n})\) be the space of piecewise continuous differentiable functions from \([ - h, 0]\) to \(R^{n}\); \(A^{T}\) means the transpose of the matrix A; B is symmetric if \(B = B^{T}\); H is positive definite (or negative definite) if \(\langle Hx,x \rangle > 0\) (or \(\langle Hx,x \rangle < 0\)) for all \(x \ne 0\); \(\Vert D \Vert \) denotes the spectral norm of matrix D; \(\lambda_{\min} (A)\) and \(\lambda_{\max} (A)\) denote the minimal and maximal eigenvalue of the matrix A, respectively.

Problem description

In this study, we consider the following fractional neutral system with variable delays:

$$ {}_{t_{0}}D_{t}^{q}x(t) - C{}_{t_{0}}D_{t}^{q}x \bigl(t - h(t)\bigr) = A_{0}x(t) + A_{1}x\bigl(t - h(t) \bigr) + B \int_{t - h(t)}^{t} x(s)\,ds,\quad t \ge 0, $$
(2.1)

with the initial conditions

$${}_{t_{0}}D_{t}^{ - (1 - q)}x(t) = \vartheta (t),\quad t \in [ - h, 0], $$

where \(0 < q < 1\), \({}_{t_{0}}D_{t}^{q}x( \cdot )\) shows a q order Riemann–Liouville fractional derivative of \(x( \cdot )\), \(x(t) \in \Re^{n}\) is the state vector, \(A_{0}, A_{1}, B, C \in \Re^{n \times n}\) are known constant matrixes, and \(h(t)\) is a variable delay function.

For \(h(t)\) variable delay, we assume that there are two different cases as follows:

Case I. \(h(t)\) is a differentiable function satisfying, for all \(t \ge 0\),

$$ 0 \le h(t) \le h\quad \mbox{and}\quad \dot{h}(t) \le \delta < 1. $$
(2.2)

Case II. \(h(t)\) is not differentiable or the upper bound of the derivative of \(h(t)\) is unknown, and \(h(t)\) holds for all \(t \ge 0\),

$$ 0 \le h(t) \le h, $$
(2.3)

where h and δ are nonnegative constants.

Before evaluating the main result, some basic definitions of fractional analysis and important lemmas are needed as given below.

Definition 2.1

([23])

The Riemann–Liouville fractional integral is described as

$${}_{t_{0}}D_{t}^{ - q}x(t) = \frac{1}{\varGamma (q)} \int_{t_{0}}^{t} (t - s)^{q - 1} x(s)\,ds\quad (q > 0). $$

Definition 2.2

([23])

The Riemann–Liouville fractional derivative is described as

$${}_{t_{0}}D_{t}^{q}x(t) = \frac{1}{\varGamma (n - q)} \frac{d^{n}}{dt^{n}} \int_{t_{0}}^{t} \frac{x(s)}{(t - s)^{q + 1 - n}}\, ds\quad (n - 1 \le q < n), $$

where Γ denotes the gamma function.

Lemma 2.1

([12])

If \(p > q > 0\), then the formula

$${}_{t_{0}}D_{t}^{q}\bigl({}_{t_{0}}D_{t}^{ - p}x(t) \bigr) = {}_{t_{0}}D_{t}^{q - p}x(t) $$

holds for “sufficiently good” functions \(x(t)\). In particular, this relation holds if \(x(t)\) is integrable.

Lemma 2.2

([9])

Let \(x(t) \in \Re^{n}\) be a vector of differentiable function for \(\forall t \ge t_{0}\). Then the following relationship holds:

$$\frac{1}{2}{}_{t_{0}}D_{t}^{q} \bigl(x^{T}(t)Mx(t)\bigr) \le x^{T}(t)M{}_{t_{0}}D_{t}^{q}x(t),\quad 0 < q < 1, $$

where \(M \in \Re^{n \times n}\) is a constant, square, symmetric, and positive semi-definite matrix.

Lemma 2.3

([33])

For all symmetric positive definite matrix \(S \in D^{n \times n}\), scalar \(\gamma > 0\), and vector function \(g:[0, \gamma ] \to R^{n}\), such that the integrations in the following inequality are well defined, we have

$$\gamma \int_{0}^{\gamma} g^{T}(s)Sg(s)\,ds \ge \biggl[ \int_{0}^{\gamma} g(s)\,ds \biggr]^{T}S \biggl[ \int_{0}^{\gamma} g(s)\,ds \biggr]. $$

Main results

In order to simplify the treatment of the problem, the operator \(L:C([ - h, 0], R^{n}) \to R^{n}\) is defined to be \(L:L(x_{t}) = x(t) - Cx(t - h(t))\).

The stability of the operator L is described as follows.

Definition 3.1

([10])

The operator L is said to be stable if the zero solution of the homogeneous difference equation \(L(x_{t}) = 0\), \(t \ge 0\), is uniformly asymptotically stable.

Lemma 3.1

([10])

The operator L is stable if \(\Vert C \Vert < 1\).

In the following Theorems 3.13.3, we give our main results for the fractional neutral system (2.1).

Theorem 3.1

Under Case I, the zero solution of system (2.1) with (2.2) is asymptotically stable if \(\Vert C \Vert < 1\), and there exist symmetric positive definite matrices P, Q, R, S, and U such that the following LMI holds:

$$ \varOmega = \left [ \textstyle\begin{array}{c@{\quad}c@{\quad}c@{\quad}c} \varOmega_{11} & \varOmega_{12} & \varOmega_{13} & \varOmega_{14} \\ \varOmega_{12}^{T} & \varOmega_{22} & \varOmega_{23} & \varOmega_{24} \\ \varOmega_{13}^{T} & \varOmega_{23}^{T} & \varOmega_{33} & \varOmega_{34} \\ \varOmega_{14}^{T} & \varOmega_{24}^{T} & \varOmega_{34}^{T} & \varOmega_{44} \end{array}\displaystyle \right ] < 0, $$
(3.1)

where

$$\begin{gathered} \varOmega_{11} = PA_{0} + A_{0}^{T}P + Q + h^{2}S + A_{0}^{T} \bigl( R + h^{2}U \bigr)A_{0},\qquad\varOmega_{12} = PA_{1} + A_{0}^{T} \bigl( R + h^{2}U \bigr)A_{1}, \\ \varOmega_{13} = PB + A_{0}^{T} \bigl( R + h^{2}U \bigr)B,\qquad\varOmega_{14} = PC + A_{0}^{T} \bigl( R + h^{2}U \bigr)C, \\ \varOmega_{22} = A_{1}^{T} \bigl( R + h^{2}U \bigr)A_{1} - (1 - \delta )Q,\qquad \varOmega_{23} = A_{1}^{T} \bigl( R + h^{2}U \bigr)B,\\ \varOmega_{24} = A_{1}^{T} \bigl( R + h^{2}U \bigr)C, \qquad \varOmega_{33} = - S + B^{T} \bigl( R + h^{2}U \bigr)B,\qquad\varOmega_{34} = B^{T} \bigl( R + h^{2}U \bigr)C,\\\varOmega_{44} = C^{T} \bigl( R + h^{2}U \bigr)C - (1 - \delta )R.\end{gathered} $$

Proof

Let us consider the following Lyapunov functional for fractional neutral system (2.1):

$$ V(t) = \sum_{k = 1}^{3} V_{k}(t),\quad t \ge 0, $$
(3.2)

where

$$\begin{gathered} V_{1}(t) = {}_{t_{0}}D_{t}^{q - 1} \bigl( x^{T}(t)Px(t) \bigr), \\ V_{2}(t) = \int_{t - h(t)}^{t} x^{T}(s)Qx(s)\,ds + \int_{ - h(t)}^{0} \bigl({}_{t_{0}}D_{t}^{q}x(t + s)\bigr)^{T}R\bigl({}_{t_{0}}D_{t}^{q}x(t + s)\bigr)\,ds, \\ V_{3}(t) = h \int_{ - h}^{0} \int_{t + \beta}^{t} x^{T}(s)Sx(s)\,ds\,d\beta + h \int_{ - h}^{0} \int_{t + \beta}^{t} \bigl({}_{t_{0}}D_{s}^{q}x(s) \bigr)^{T}U\bigl({}_{t_{0}}D_{s}^{q}x(s) \bigr)\,ds\,d\beta.\end{gathered} $$

From Definitions 2.1 and 2.2, we know that \(V_{1}(t)\), \(V_{2}(t)\), and \(V_{3}(t)\) are positive definite functionals. It follows from (2.2) and Lemmas 2.1 and 2.2 that we get the time derivative \(V(t)\) along the trajectories of fractional system (2.1) as follows:

$$\dot{V}(t) = \sum_{k = 1}^{3} \dot{V}_{k} (t), $$

where

$$\begin{aligned}& \begin{aligned}[b] \dot{V}_{1}(t) ={}& {}_{t_{0}}D_{t}^{q} \bigl(x^{T}(t)Px(t)\bigr) \\\le{}& 2x^{T}(t)P{}_{t_{0}}D_{t}^{q} \bigl(x(t)\bigr) \\ ={}& 2x^{T}(t)P\biggl[A_{0}x(t) + A_{1}x\bigl(t - h(t)\bigr) + B \int_{t - h(t)}^{t} x(s)\,ds + C{}_{t_{0}}D_{t}^{q}x \bigl(t - h(t)\bigr)\biggr] \\ ={}& x^{T}(t) \bigl(PA_{0} + A_{0}^{T}P \bigr)x(t) + 2x^{T}(t)PA_{1}x\bigl(t - h(t)\bigr) + 2x^{T}(t)PB \int_{t - h(t)}^{t} x(s)\,ds \\ &+ 2x^{T}(t)PC{}_{t_{0}}D_{t}^{q}x\bigl(t - h(t)\bigr),\end{aligned} \end{aligned}$$
(3.3)
$$\begin{aligned}& \begin{aligned}[b]\dot{V}_{2}(t) ={}& x^{T}(t)Qx(t) - \bigl(1 - \dot{h}(t) \bigr)x^{T}\bigl(t - h(t)\bigr)Qx\bigl(t - h(t)\bigr) + \bigl({}_{t_{0}}D_{t}^{q}x(t)\bigr)^{T}R \bigl({}_{t_{0}}D_{t}^{q}x(t)\bigr) \\ &- \bigl(1 - \dot{h}(t)\bigr) \bigl({}_{t_{0}}D_{t}^{q}x \bigl(t - h(t)\bigr)\bigr)^{T}R\bigl({}_{t_{0}}D_{t}^{q}x \bigl(t - h(t)\bigr)\bigr) \\ \le{}& x^{T}(t)Qx(t) - (1 - \delta )x^{T}\bigl(t - h(t)\bigr)Qx \bigl(t - h(t)\bigr) + \bigl({}_{t_{0}}D_{t}^{q}x(t) \bigr)^{T}R\bigl({}_{t_{0}}D_{t}^{q}x(t) \bigr) \\ &- (1 - \delta ) \bigl({}_{t_{0}}D_{t}^{q}x\bigl(t - h(t)\bigr)\bigr)^{T}R\bigl({}_{t_{0}}D_{t}^{q}x \bigl(t - h(t)\bigr)\bigr),\end{aligned} \end{aligned}$$
(3.4)
$$\begin{aligned}& \begin{aligned}[b] \dot{V}_{3}(t) ={}& h^{2}x^{T}(t)Sx(t) - h \int_{t - h}^{t} x^{T}(s)Sx(s)\,ds + h^{2}\bigl({}_{t_{0}}D_{t}^{q}x(t) \bigr)^{T}U\bigl({}_{t_{0}}D_{t}^{q}x(t) \bigr) \\ &- h \int_{t - h}^{t} \bigl({}_{t_{0}}D_{s}^{q}x(s) \bigr)^{T}U\bigl({}_{t_{0}}D_{s}^{q}x(s) \bigr)\,ds \\ \le{}& h^{2}x^{T}(t)Sx(t) - h \int_{t - h}^{t} x^{T}(s)Sx(s)\,ds + h^{2}\bigl({}_{t_{0}}D_{t}^{q}x(t) \bigr)^{T}U\bigl({}_{t_{0}}D_{t}^{q}x(t) \bigr).\end{aligned} \end{aligned}$$
(3.5)

Obviously, for any scalar\(s \in [t - h, t]\), and by Lemma 2.3, we have

$$\begin{aligned}[b] - h \int_{t - h}^{t} x^{T}(s)Sx(s)\,ds &\le - h \int_{t - h(t)}^{t} x^{T}(s)Sx(s)\,ds \\&\le - \biggl( \int_{t - h(t)}^{t} x(s)\,ds \biggr)^{T}S \biggl( \int_{t - h(t)}^{t} x(s)\,ds \biggr).\end{aligned} $$
(3.6)

Taking into account (3.4) and (3.5), we get

$$\begin{aligned}[b] &\bigl({}_{t_{0}}D_{t}^{q}x(t)\bigr)^{T}R \bigl({}_{t_{0}}D_{t}^{q}x(t)\bigr) + h^{2} \bigl({}_{t_{0}}D_{t}^{q}x(t)\bigr)^{T}U \bigl({}_{t_{0}}D_{t}^{q}x(t)\bigr) \\ &\quad= \biggl[A_{0}x(t) + A_{1}x\bigl(t - h(t)\bigr) + B \int_{t - h(t)}^{t} x(s)\,ds + C{}_{t_{0}}D_{t}^{q}x \bigl(t - h(t)\bigr)\biggr]^{T} \bigl( R + h^{2}U \bigr) \\ &\qquad{}\times \biggl[A_{0}x(t) + A_{1}x\bigl(t - h(t)\bigr) + B \int_{t - h(t)}^{t} x(s)\,ds + C{}_{t_{0}}D_{t}^{q}x \bigl(t - h(t)\bigr)\biggr] \\ &\quad= x^{T}(t)A_{0}^{T} \bigl( R + h^{2}U \bigr)A_{0}x(t) + x^{T}(t)A_{0}^{T} \bigl( R + h^{2}U \bigr)A_{1}x\bigl(t - h(t)\bigr) \\ &\qquad{}+ x^{T}(t)A_{0}^{T} \bigl( R + h^{2}U \bigr)B \int_{t - h(t)}^{t} x(s)\,ds + x^{T}(t)A_{0}^{T} \bigl( R + h^{2}U \bigr)C{}_{t_{0}}D_{t}^{q}x \bigl(t - h(t)\bigr) \\ &\qquad{}+ x^{T}\bigl(t - h(t)\bigr)A_{1}^{T} \bigl( R + h^{2}U \bigr)A_{0}x(t) + x^{T}\bigl(t - h(t) \bigr)A_{1}^{T} \bigl( R + h^{2}U \bigr)A_{1}x\bigl(t - h(t)\bigr) \\ &\qquad{}+ x^{T}\bigl(t - h(t)\bigr)A_{1}^{T} \bigl( R + h^{2}U \bigr)B \int_{t - h(t)}^{t} x(s)\,ds \\ &\qquad{}+ x^{T}\bigl(t - h(t) \bigr)A_{1}^{T} \bigl( R + h^{2}U \bigr)C {}_{t_{0}}D_{t}^{q}x\bigl(t - h(t)\bigr)\\ &\qquad{} + \biggl( \int_{t - h(t)}^{t} x(s)\,ds \biggr)^{T}B^{T} \bigl( R + h^{2}U \bigr)A_{0}x(t) \\ &\qquad{}+ \biggl( \int_{t - h(t)}^{t} x(s)\,ds \biggr)^{T}B^{T} \bigl( R + h^{2}U \bigr) A_{1}x\bigl(t - h(t)\bigr) \\ &\qquad{}+ \biggl( \int_{t - h(t)}^{t} x(s)\,ds \biggr)^{T}B^{T} \bigl( R + h^{2}U \bigr)B \int_{t - h(t)}^{t} x(s)\,ds \\ &\quad\quad{} + \biggl( \int_{t - h(t)}^{t} x(s)\,ds \biggr)^{T}B^{T}\bigl( R + h^{2}U \bigr)C{}_{t_{0}}D_{t}^{q}x \bigl(t - h(t)\bigr)\\ &\qquad{} + \bigl({}_{t_{0}}D_{t}^{q}x \bigl(t - h(t)\bigr)\bigr)^{T}C^{T} \bigl( R + h^{2}U \bigr)A_{0}x(t) \\ &\qquad{}+ \bigl({}_{t_{0}}D_{t}^{q}x\bigl(t - h(t)\bigr) \bigr)^{T}C^{T} \bigl( R + h^{2}U \bigr)A_{1}x\bigl(t - h(t)\bigr) \\ &\qquad{}+ \bigl({}_{t_{0}}D_{t}^{q}x \bigl(t - h(t)\bigr)\bigr)^{T}C^{T} \bigl( R + h^{2}U \bigr)B\int_{t - h(t)}^{t} x(s)\,ds \\ &\qquad{} + \bigl({}_{t_{0}}D_{t}^{q}x \bigl(t - h(t)\bigr)\bigr)^{T}C^{T} \bigl( R + h^{2}U \bigr)C{}_{t_{0}}D_{t}^{q}x\bigl(t - h(t)\bigr).\end{aligned} $$
(3.7)

From (3.3)–(3.7), we obtain

$$\dot{V}(t) \le \eta^{T}(t)\varOmega \eta (t), $$

where

$$\eta^{T} = \bigl[ \textstyle\begin{array}{c@{\quad}c@{\quad}c@{\quad}c} x^{T}(t) & x^{T}(t - h(t)) & (\int_{t - h(t)}^{t} x(s)\,ds )^{T} & ({}_{t_{0}}D_{t}^{q}x(t - h(t)))^{T} \end{array}\displaystyle \bigr]$$

and Ω is defined in (3.1). If \(\varOmega < 0\), \(\dot{V}(t)\) is negative definite for \(\eta (t) \ne 0\). This implies that the system fractional (2.1) is asymptotically stable. Thus, the proof is complete. □

Remark 3.1

A new criterion on delay-independent stability will be obtained if we choose a different Lyapunov functional.

Theorem 3.2

Under Case I, the zero solution of system (2.1) with (2.2) is asymptotically stable if \(\Vert C \Vert < 1\), and there exist symmetric positive definite matrices P, Q, S, and U such that the following LMI holds:

$$\begin{aligned}[b] \varSigma& = \left [ \textstyle\begin{array}{c@{\quad}c@{\quad}c} PA_{0} + A_{0}^{T}P + Q + h^{2}S + h^{2}A_{0}^{T}UA_{0} & PA_{1} - A_{0}^{T}PC + h^{2}A_{0}^{T}UA_{1} & PB + h^{2}A_{0}^{T}UB \\ A_{1}^{T}P - C^{T}PA_{0} + h^{2}A_{1}^{T}UA_{0} & h^{2}A_{1}^{T}UA_{1} - 2C^{T}PA_{1} - (1 - \delta )Q & h^{2}A_{1}^{T}UB - C^{T}PB \\ B^{T}P + h^{2}B^{T}UA_{0} & h^{2}B^{T}UA_{1} - B^{T}PC & h^{2}B^{T}UB - S \end{array}\displaystyle \right ] \hspace{-24pt}\\&< 0.\end{aligned} $$
(3.8)

Proof

Let us consider the following Lyapunov functional for fractional neutral system (2.1):

$$\begin{aligned}[b] W(t) ={}& {}_{t_{0}}D_{t}^{q - 1}\bigl(\bigl(L(x_{t}) \bigr)^{T}P\bigl(L(x_{t})\bigr)\bigr) + \int_{t - h(t)}^{t} x^{T}(s)Qx(s)\,ds + h \int_{ - h}^{0} \int_{t + \beta}^{t} x^{T}(s)Sx(s)\,ds\,d\beta\hspace{-12pt} \\ &+ h \int_{ - h}^{0} \int_{t + \beta}^{t} ({}_{t_{0}}D_{s}^{q} \bigl(L(x_{s})\bigr)^{T}U\bigl({}_{t_{0}}D_{s}^{q} \bigl(L(x_{s})\bigr)\bigr)\,ds\,d\beta.\end{aligned} $$
(3.9)

It follows from (2.2) and Lemmas 2.1 and 2.2 that we get the time derivative \(W(t)\) along the trajectories of system (2.1) as follows:

$$\begin{aligned} \dot{W}(t) \le{}& 2\bigl(x(t) - Cx\bigl(t - h(t)\bigr)\bigr)^{T}P \biggl[A_{0}x(t) + A_{1}x\bigl(t - h(t)\bigr) + B \int_{t - h(t)}^{t} x(s)\,ds \biggr] \\ &+ x^{T}(t)Qx(t) - \bigl(1 - \dot{h}(t)\bigr)x^{T}\bigl(t - h(t)\bigr)Qx\bigl(t - h(t)\bigr) \\ &+ h^{2}x^{T}(t)Sx(t) - h \int_{t - h}^{t} x^{T}(s)Sx(s)\,ds \\ &+ h^{2}\bigl({}_{t_{0}}D_{t}^{q}\bigl(x(t) - Cx\bigl(t - h(t)\bigr)\bigr)\bigr)^{T}U\bigl({}_{t_{0}}D_{t}^{q} \bigl(x(t) - Cx\bigl(t - h(t)\bigr)\bigr)\bigr) \\ &- h \int_{t - h}^{t} \bigl({}_{t_{0}}D_{s}^{q} \bigl(x(s) - Cx\bigl(s - h(s)\bigr)\bigr)\bigr)^{T}U \bigl({}_{t_{0}}D_{t}^{q}\bigl(x(s) - Cx\bigl(s - h(s) \bigr)\bigr)\bigr)\,ds \\ \le{}& x^{T}(t) \bigl(PA_{0} + A_{0}^{T}P \bigr)x(t) + 2x^{T}(t)PA_{1}x\bigl(t - h(t)\bigr) + 2x^{T}(t)PB \int_{t - h(t)}^{t} x(s)\,ds \\ &- 2x^{T}\bigl(t - h(t)\bigr)C^{T}PA_{0}x(t) - 2x^{T}\bigl(t - h(t)\bigr)C^{T}PA_{1}x\bigl(t - h(t)\bigr) \\ &- 2x^{T}\bigl(t - h(t)\bigr)C^{T}PB \int_{t - h(t)}^{t} x(s)\,ds + x^{T}(t)Qx(t) \\ &- (1 - \delta )x^{T}\bigl(t - h(t)\bigr)Qx\bigl(t - h(t)\bigr) + h^{2}x^{T}(t)Sx(t) - h \int_{t - h}^{t} x^{T}(s)Sx(s)\,ds \\ &+ h^{2}x^{T}(t)A_{0}^{T}UA_{0}x(t) + h^{2}x^{T}(t)A_{0}^{T}UA_{1}x \bigl(t - h(t)\bigr) \\ &+ h^{2}x^{T}(t)A_{0}^{T}UB \int_{t - h(t)}^{t} x(s)\,ds + h^{2}x^{T} \bigl(t - h(t)\bigr)A_{1}^{T}UA_{0}x(t) \\ &+ h^{2}x^{T}\bigl(t - h(t)\bigr)A_{1}^{T}UA_{1}x \bigl(t - h(t)\bigr) + h^{2}x^{T}\bigl(t - h(t) \bigr)A_{1}^{T}UB \int_{t - h(t)}^{t} x(s)\,ds \\ &+ h^{2}\biggl( \int_{t - h(t)}^{t} x(s)\,ds \biggr)^{T}B^{T}UA_{0}x(t) + h^{2}\biggl( \int_{t - h(t)}^{t} x(s)\,ds \biggr)^{T}B^{T}UA_{1}x \bigl(t - h(t)\bigr) \\ &+ h^{2}\biggl( \int_{t - h(t)}^{t} x(s)\,ds \biggr)^{T}B^{T}UB \int_{t - h(t)}^{t} x(s)\,ds. \end{aligned}$$
(3.10)

Obviously, for any scalar \(s \in [t - h, t]\), and by Lemma 2.3, we have

$$\begin{aligned}[b] - h \int_{t - h}^{t} x^{T}(s)Sx(s)\,ds &\le - h \int_{t - h(t)}^{t} x^{T}(s)Sx(s)\,ds \\&\le - \biggl( \int_{t - h(t)}^{t} x(s)\,ds \biggr)^{T}S \biggl( \int_{t - h(t)}^{t} x(s)\,ds \biggr).\end{aligned} $$
(3.11)

From (3.10) and (3.11), we obtain

$$\dot{W}(t) \le \xi^{T}(t)\varSigma \xi (t), $$

where

$$\xi^{T} = \bigl[\textstyle\begin{array}{c@{\quad}c@{\quad}c} x^{T}(t) & x^{T}(t - h(t)) & (\int_{t - h(t)}^{t} x(s)\,ds )^{T} \end{array}\displaystyle \bigr]$$

and Σ is defined in (3.8). If \(\varSigma < 0\), \(\dot{W}(t)\) is negative definite for \(\xi (t) \ne 0\). This implies that system (2.1) is asymptotically stable. Thus, the proof is complete. □

Theorem 3.3

Under Case II, the zero solution of system (2.1) with (2.3) is asymptotically stable if \(\Vert C \Vert < 1\), and there exist symmetric positive definite matrices P, S, and U such that the following LMI holds:

$$ \begin{aligned}[b] \varXi &= \left [ \textstyle\begin{array}{c@{\quad}c@{\quad}c} PA_{0} + A_{0}^{T}P + h^{2}S + h^{2}A_{0}^{T}UA_{0} & PA_{1} - A_{0}^{T}PC + h^{2}A_{0}^{T}UA_{1} & PB + h^{2}A_{0}^{T}UB \\ A_{1}^{T}P - C^{T}PA_{0} + h^{2}A_{1}^{T}UA_{0} & h^{2}A_{1}^{T}UA_{1} - 2C^{T}PA_{1} & h^{2}A_{1}^{T}UB - C^{T}PB \\ B^{T}P + h^{2}B^{T}UA_{0} & h^{2}B^{T}UA_{1} - B^{T}PC & h^{2}B^{T}UB - S \end{array}\displaystyle \right ] \hspace{-48pt}\\&< 0.\end{aligned} $$
(3.12)

Proof

In Case II, a Lyapunov functional can be chosen as (3.9) with \(Q = 0\). Similar to the above analysis, one can get that \(\dot{W}(t) < 0\) holds if \(\varXi < 0\). Thus, the proof of Theorem 3.3 is complete. □

Numerical examples and simulation results

To illustrate the effectiveness and applicability of the proposed method, the following three numerical examples are presented.

Example 4.1

As a special case of system (2.1), consider the following fractional neutral system with variable delay:

$$ {}_{t_{0}}D_{t}^{q} \bigl( x(t) - Cx\bigl(t - h(t) \bigr) \bigr) = A_{0}x(t) + A_{1}x\bigl(t - h(t)\bigr) + B \int_{t - h(t)}^{t} x(s)\,ds, \quad t \ge 0, $$
(4.1)

where \(q \in (0, 1)\), \(x(t) = [ x_{1}(t), x_{2}(t) ]^{T}\),

$$\begin{gathered} A_{0} = \left [ \textstyle\begin{array}{c@{\quad}c} - 4 & 3 \\ 0 & - 2 \end{array}\displaystyle \right ], \qquad A_{1} = \left [ \textstyle\begin{array}{c@{\quad}c} 0.3 & 0.2 \\ 0 & 0.2 \end{array}\displaystyle \right ],\\ B = \left [ \textstyle\begin{array}{c@{\quad}c} 0.03 & 0 \\ 0 & 0.01 \end{array}\displaystyle \right ],\qquad C = \left [ \textstyle\begin{array}{c@{\quad}c} 0.12 & 0 \\ 0 & 0.18 \end{array}\displaystyle \right ],\end{gathered} $$

and

$$ 0.2 \le h(t) = 0.2 + 0.3\sin^{2}(t) \le 0.5. $$
(4.2)

Let us choose

$$\begin{gathered} P = \left [ \textstyle\begin{array}{c@{\quad}c} 8 & 0 \\ 0 & 7 \end{array}\displaystyle \right ],\qquad Q = \left [ \textstyle\begin{array}{c@{\quad}c} 4 & 0 \\ 0 & 4 \end{array}\displaystyle \right ],\qquad R = \left [ \textstyle\begin{array}{c@{\quad}c} 1.5 & 0.5 \\ 0.5 & 1.5 \end{array}\displaystyle \right ],\\ S = \left [ \textstyle\begin{array}{c@{\quad}c} 0.12 & 0 \\ 0 & 0.1 \end{array}\displaystyle \right ],\qquad U = \left [ \textstyle\begin{array}{c@{\quad}c} 1.2 & 0.1 \\ 0.1 & 1.2 \end{array}\displaystyle \right ].\end{gathered} $$

Under the above assumptions, all eigenvalues of the LMI described by (3.1) are \(\lambda_{\max} (\varOmega ) \le - 0.0969\) by using MATLAB-Simulink.

As a result, condition (3.1) holds, which implies that the zero solution of system (4.1) with (4.2) is asymptotically stable according to Theorem 3.1.

Example 4.2

As a special case of system (2.1), consider the following fractional neutral system with variable delay:

$$ {}_{t_{0}}D_{t}^{q} \bigl( x(t) - Cx\bigl(t - h(t) \bigr) \bigr) = A_{0}x(t) + A_{1}x\bigl(t - h(t)\bigr) + B \int_{t - h(t)}^{t} x(s)\,ds,\quad t \ge 0, $$
(4.3)

where \(q \in (0, 1)\), \(x(t) = [ x_{1}(t), x_{2}(t) ]^{T}\),

$$\begin{gathered} A_{0} = \left [ \textstyle\begin{array}{c@{\quad}c} - 6 & 0 \\ 2 & - 1 \end{array}\displaystyle \right ],\qquad A_{1} = \left [ \textstyle\begin{array}{c@{\quad}c} 1 & 0.3 \\ 0.2 & 0 \end{array}\displaystyle \right ],\\ B = \left [ \textstyle\begin{array}{c@{\quad}c} 0.02 & 0 \\ 0 & 0.1 \end{array}\displaystyle \right ],\qquad C = \left [ \textstyle\begin{array}{c@{\quad}c} 0.14 & 0 \\ 0 & 0.16 \end{array}\displaystyle \right ],\end{gathered} $$

and

$$ 0.4 \le \tau_{1}(t) = 0.4 + 0.2\sin^{2}(t) \le 0.6. $$
(4.4)

Let us choose

$$P = \left [ \textstyle\begin{array}{c@{\quad}c} 7 & 0 \\ 0 & 5 \end{array}\displaystyle \right ],\qquad Q = \left [ \textstyle\begin{array}{c@{\quad}c} 4 & 1 \\ 1 & 2 \end{array}\displaystyle \right ],\qquad S = \left [ \textstyle\begin{array}{c@{\quad}c} 2.4 & 0.3 \\ 0.3 & 2.4 \end{array}\displaystyle \right ],\qquad U = \left [ \textstyle\begin{array}{c@{\quad}c} 1 & 0.2 \\ 0.2 & 1 \end{array}\displaystyle \right ]. $$

Under the above assumptions, all eigenvalues of the LMI described by (3.8) are \(\lambda_{\max} (\varSigma ) \le - 1.0417\) by using MATLAB-Simulink.

As a result, condition (3.8) holds, which implies that the zero solution of system (4.3) with (4.4) is asymptotically stable according to Theorem 3.2.

Example 4.3

As a special case of system (2.1), consider the following fractional neutral system with variable delay:

$$ {}_{t_{0}}D_{t}^{q} \bigl( x(t) - Cx\bigl(t - h(t) \bigr) \bigr) = A_{0}x(t) + A_{1}x\bigl(t - h(t)\bigr) + B \int_{t - h(t)}^{t} x(s)\,ds,\quad t \ge 0, $$
(4.5)

where \(q \in (0, 1)\), \(x(t) = [ x_{1}(t), x_{2}(t) ]^{T}\),

$$\begin{gathered} A_{0} = \left [ \textstyle\begin{array}{c@{\quad}c} - 10 & - 0.2 \\ - 0.6 & - 1 \end{array}\displaystyle \right ],\qquad A_{1} = \left [ \textstyle\begin{array}{c@{\quad}c} 1.4 & 0.4 \\ 0.8 & 0.2 \end{array}\displaystyle \right ],\\ B = \left [ \textstyle\begin{array}{c@{\quad}c} 0.9 & 0 \\ 0 & 0.1 \end{array}\displaystyle \right ],\qquad C = \left [ \textstyle\begin{array}{c@{\quad}c} 0.12 & 0 \\ 0 & 0.2 \end{array}\displaystyle \right ], \end{gathered} $$

and

$$ \left \{ \textstyle\begin{array}{l@{\quad}l} r(t) = 0.1 + 0.2\sin^{2}(t) \le 0.3,& \text{if }t \in I = \bigcup_{k \ge 0}[2{k}\pi,(2{k} + 1)\pi ], \\ r(t) = 0,& t \in \Re^{ +} /I. \end{array}\displaystyle \right . $$
(4.6)

Let us choose

$$P = \left [ \textstyle\begin{array}{c@{\quad}c} 5.8 & 0 \\ 0 & 1 \end{array}\displaystyle \right ],\qquad S = \left [ \textstyle\begin{array}{c@{\quad}c} 1.4 & 0.5 \\ 0.5 & 1.2 \end{array}\displaystyle \right ],\qquad U = \left [ \textstyle\begin{array}{c@{\quad}c} 1 & 0.3 \\ 0.3 & 0.5 \end{array}\displaystyle \right ]. $$

Under the above assumptions, all eigenvalues of the LMI described by (3.12) are \(\lambda_{\max} (\varXi ) \le - 0.0352\) by using MATLAB-Simulink.

As a result, condition (3.12) holds, which implies that the zero solution of system (4.5) with (4.6) is asymptotically stable according to Theorem 3.3.

When the theoretical solutions of the above examples (Examples 4.1, 4.2, and 4.3) are examined, it is seen that the zero solution of the considered systems in the examples is stable after a certain time interval under different initial conditions. These are confirmed by the related simulation results (Figs. 1, 2, 3).

Figure 1
figure1

The simulation of Example 4.1 for (4.2)

Figure 2
figure2

The simulation of Example 4.2 for (4.4)

Figure 3
figure3

The simulation of Example 4.3 for (4.6)

When the results of this study are compared with the results of similar studies in the literature, time delay was taken constant in the examples given in the studies which were published before [13 and 16]. The theoretical results in these studies were not supported by simulation studies. However, this proposed study is more general, and the time delay depends on the variable and the theoretical results are supported by simulations.

Conclusions

In this paper, asymptotic stability of Riemann–Liouville fractional neutral systems with variable delays has been investigated and some new sufficient conditions have been proposed. The obtained results are described by constructing appropriate Lyapunov functional and formulating in the form of LMIs, which are convenient and feasible to test the stability. The proposed met hod avoids computing Riemann–Liouville fractional-order derivatives of the Lyapunov functionals. When compared with the stability criteria in the related literature, our criteria are simple and suitable for application. Three numerical examples are given with their simulations (Fig. 1, Fig. 2, and Fig. 3) to demonstrate the effectiveness of the stability criteria of the considered system. It is observed that the numerical examples and simulation results verify the efficiency and accuracy of the theoretical results of this paper. The results of this study can be solved numerically by some recent methodologies such as those discussed in [39] and [40]. Consequently, the obtained results in this study extend and generalize the existing ones in the literature.

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Altun, Y. Further results on the asymptotic stability of Riemann–Liouville fractional neutral systems with variable delays. Adv Differ Equ 2019, 437 (2019) doi:10.1186/s13662-019-2366-z

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MSC

  • 34K20
  • 34K37
  • 34K40

Keywords

  • Asymptotic stability
  • Riemann–Liouville fractional neutral systems
  • Lyapunov functional
  • LMI
  • Variable delay