Dissipativity Analysis for a Class of Discrete-Time Neutral Stochastic Nonlinear Systems with Time Delay

(is paper focuses on the problem of dissipativity analysis for a class of discrete-time neutral stochastic nonlinear systems (DTNSNSs) with time delay and parameter uncertainties. Different from the existing results on this topic of neutral system, a kind of discretizing the neutral system is considered. Firstly, a sufficient condition of the dissipativity, which is dependent on the solution of the Lyapunov–Krasovskii technique and linear matrix inequalities (LMIs), is established. Moreover, the state-feedback controller is designed to guarantee the dissipative performance of the closed-loop system. (e effectiveness of the theoretical results is finally demonstrated by a numerical example.


Introduction
Time delay is an ubiquitous phenomenon in nature, which is the main reason of oscillation, instability, and bad system performance of the control system. As a result, the problem of time delay is inevitably involved in many control systems [1][2][3][4][5]. At the same time, it is not only the time delay that has an impact on the system; random factors also exist objectively in the actual production, and the influence of random errors can hardly be ignored [1,[6][7][8][9][10][11][12]. Accordingly, the work of a stochastic time-delay system is particularly important.
In the research of stochastic time-delay systems, neutral stochastic time-delay systems are a special and crucial kind of control systems with time delay, which are widely used in natural science and engineering technology, such as economics, automatic control theory, medicine, biology, and chemistry. Neutral time-delay systems are those in which both the state and state derivative are delayed. Furthermore, the delay in general system state is called discrete delay, and the delay in system state derivative is called neutral delay, which can reflect the change law of things more profoundly and accurately and reveal the essence of things. erefore, it is necessary to study the neutral stochastic delay systems, which have captured the attention of a large number of scholars [1,[8][9][10].
As we all know, most phenomena in nature are described by nonlinear systems [3,[13][14][15][16]. Although the research results of stochastic nonlinear systems are not as much as those of linear stochastic systems, there are also rich achievements [2,[17][18][19][20][21][22]. Based on fixed point theory, Wu et al. [17] investigated the asymptotic mean square stability of the nonlinear neutral stochastic differential equations with time-varying delays. Without assuming linear growth conditions, Shen et al. [19] studied the boundedness and exponential stability of the exact solution, whose results can be applied to practical applications. e notion of dissipative in control systems has caused many scholars' concern since it was introduced by Willems firstly [23], due to its wide applications in control theory and practical systems such as robotic systems, electromechanical systems, power systems, internal combustion engine engineering, and chemical processes [3,11,[24][25][26]. Dissipativity is a very important concept in a control system, and as special cases, the concepts of H ∞ performance and passivity exist widely in the fields of physics, applied mathematics, and mechanics, (see, for example, [26,27]. By constructing an appropriate Lyapunov-Krasovskii Functional (LKF), Cao et al. [3] focused on the problem of the global asymptotic stability and dissipativity problem for a class of neutral-type stochastic Markovian Jump Static Neural Networks (NTSMJSNNs) with time-varying delays. Yang [25] probed the robust control problem of nonlinear time-delay systems based on dissipative analysis. e problem of extended dissipativity analysis for delayed uncertain discrete-time singular neural networks (DTSNNs) with Markovian jump parameters and stochastic behavior was studied in [11]. By utilizing the linearization technique, Hanmei Wang and Jun Zhao have investigated passivity and H ∞ control of switched discrete-time nonlinear systems [26]. In a discrete system, namely, the discrete time system, the variables of all or key components of the system exist in the form of discrete signals, and the state of the system changes at discrete time points. Discrete systems need to be described by difference equations, which are widely used in social, economic, and engineering systems, such as automata, impulse control, sampling regulation, and digital control [12,[27][28][29][30]. In practical control systems, some discrete dynamical systems described by difference equations are often encountered. e stability research of them in the sense of Lyapunov-Krasovskii has been poured enough attention into [31,32]. However, due to the existence of the neutral items x(s + 1 − τ), there are few results of the work on discrete-time neutral systems [32].
In this paper, we discuss a dissipative analysis problem for discrete-time neutral stochastic nonlinear systems (DTNSNSs) with time delay.
e problem under consideration is to design a state-feedback controller for DTNSNSs with time delay such that the resulting closed-loop system is not only asymptotically stable in the mean square but also satisfies the strictly (X, Y, Z)-dissipative condition. Using linear matrix inequalities, a sufficient condition for the solvability of the problem is established. When the condition is satisfied, the desired feedback controller is also obtained for DTNSNSs with time delay and parameter uncertainties. e rest of this paper is structured as follows. In Section 2, a model description and preliminaries are stated. Our main results are provided in Section 3. In Section 4, simulation results are presented to explain the correctness of the theoretical methods. Finally, conclusions are drawn in Section 5.

Model Description and Preliminaries
We consider the following discrete-time neutral stochastic nonlinear systems (DTNSNSs) with time delay and parameter uncertainties where d is a time delay, τ denotes a neutral delay, x(s) ∈ R n is the state variable, v(s) ∈ R q is the exogenous disturbance input or a reference signal, u(s) ∈ R n is the control input, z(s) ∈ R p is the control output vector, φ(s) is a continuous vector-valued initial function, f(s, x(s)), f d (s, x (s − d)) ∈ R n × R n represent unknown nonlinear functions which describe the structure uncertainty of the system, and w(s) is a scalar Brownian motion on the complete probability space in which M 1 , M 2 , M 3 , N 1 , N 2 are determinate constant matrices with appropriate dimensions and Δ(s) is an unknown real time-varying matrix function with Lebesgue norm measurable elements satisfying e parameter uncertainties are said to be admissible if both (2) and (3) hold. When Δ(s) � 0, the system is referred to as a nominal system. Remark 1. Generally speaking, the structure of the parameter uncertainties with the form (2) and (3) has been widely considered in practical problems of control systems including both continuous and discrete time [1,9,18,30]. Compared with the novel framework of discrete-time neutral systems [32], the stochastic and nonlinear perturbations are taken into this paper, which makes the model more practical.
For systems (1), we design the following state feedback controller: in which the matrix K is the gain matrix, which is to be designed. erefore, the closed-loop DTNSNSs with time delay and parameter uncertainties can be rewritten as In the first place, we make the following assumptions.

Assumption 1.
e unknown nonlinear perturbations f(s, x(s)), f d (s, x(s − d)) satisfy the following condition: where α, β are the given positive real constants and R is a matrix with appropriate dimensions. As a matter of fact, Assumption 1 is more general and has significant implications for dealing with the nonlinear function of the system [25].
Assumption 2. Without loss of generity, for the neutral term μ(x(s + 1 − τ)), it satisfies the following condition: In fact, the abovementioned inequality is equivalent to Before presenting the main results of this paper, two definitions for the DTNSNSs (1) with time delay are introduced, which will be necessary for the derivations of following theorems.
For systems (1), the energy supply function is defined as where the matrices Definition 2 (see [4]). Given supply rates function Φ(v, z, N), the DTNSNSs (1) with time delay are called (X, Y, Z)-dissipative if under zero initial condition, the energy supply function satisfies Furthermore, if there exists a small enough scalar ϱ > 0, e DTNSNSs (1) with time delay are called strictly (X, Y, Z)-dissipative.

Remark 2.
e abovementioned performance of strict (X, Y, Z)-dissipativity includes the H ∞ performance and passivity as special cases, which are listed as follows: (1) When X � −I, Y � 0, and Z � c 2 I, strictly (X, Y, Z)-dissipative, (13) reduces to an H ∞ performance requirement (2) When X � 0, Y � I, and Z � 0, (1) corresponds to a strict passive problem In addition, the following lemmas are used for proving our desired results.
Lemma 1 (see [2]). Let a ∈ R n , b ∈ R n , and ε > 0; then, we have Lemma 2 (see [14]). For the given symmetric matrix Σ and matrices D and L with appropriate dimensions, Discrete Dynamics in Nature and Society Lemma 3 (see [21]) (Schur Complement). Given one positive definite matrix G 2 > 0 and constant matrices G 1 and G 3 , e aim is to study the stability and dissipativity analysis for DTNSNSs with time delay and parameter uncertainties.

Dissipativity Analysis for DTNSNSs with Time Delay
Theorem 1. We consider u(s) � 0 of the DTNSNSs (5) with time delay and parameter uncertainties.
Proof. We construct the following Lyapunov-Krasovskii functional as follows: with Calculating the forward difference of V j (s) as ΔV j (s) � V j (s + 1) − V j (s) and taking the mathematical expectation, we obtain Accordingly, Discrete Dynamics in Nature and Society By virtue of Lemma 1 and Assumption 1, we proceed to express Similar to the derivation given above, we denote Discrete Dynamics in Nature and Society Together with Lemma 1 and Assumptions 1 and 2, we get

Substituting (23)-(27) into (22), it can be derived that
where Discrete Dynamics in Nature and Society For simplicity, let erefore, ℷ 11 , ℷ 22 , ℷ 33 , and ℷ 44 can be rewritten as follows: First of all, we aim to prove that the DTNSNSs (5) with time delay are stochastic mean square asymptotic stability.
By means of (37), we have As a consequence, for any integer N > 0, summing up both sides of (40), from s � 0 to s � N − 1, and taking the mathematical expectation, it follows that On account of the zero initial condition, (41) means that en, by Definition 2, the DTNSNSs (5) with time delay are strictly (X, Y, Z)-dissipative.
us, the proof is completed.

Remark 3.
In the proof of eorem 1, we consider the existence of nonlinear perturbations f(s, x(s)) and f d (s, x(s − d)) and the neutral term μ(x(s + 1 − τ)) of DTNSNSs (5) with time delay and parameter uncertainties, which are more complicated and laboured than that of general time-delay systems [12,30,32], and the inequality techniques are used. In order to solve them by LMI technology, we make the following: (1) the items containing matrix (P + Q 2 ) in (22) are separated into the items containing matrix P and matrix Q 2 , respectively, processed separately, and then, added, so that they can be converted into linear matrices; (2) by analyzing the relationship between ε −1 j (j � 1, 2, . . . , 16), λ † ( † � 1, 2, 3, 4, 5) are introduced to reduce the dimensions of the matrices (17).

State-Feedback Controller Design for DTNSNSs with Time
Delay. In this part, the state-feedback controller for DTNSNSs (5) with time delay and parameter uncertainties is designed, and the following theorem is given in terms of LMI.

Conclusions
e problem of dissipativity analysis for discrete-time neutral stochastic nonlinear systems (DTNSNSs) with time delay and parameter uncertainties has been investigated in this paper. A sufficient condition has been proposed by constructing a discrete-time Lyapunov-Krasovskii functional (LKF), which guarantees the DTNSNSs to be asymptotically stochastically stable in the mean square and strictly (X, Y, Z)-dissipative. In light of this condition, a feedback controller of DTNSNSs with timedelay has been designed to ensure the stability and strictly dissipative performance of the resulting closed-loop system. At last, a numerical example has been demonstrated to validate the proposed results.

Data Availability
No data were used to support this study.