New Stabilization for Dynamical System with Two Additive Time-Varying Delays

This paper provides a new delay-dependent stabilization criterion for systems with two additive time-varying delays. The novel functional is constructed, a tighter upper bound of the derivative of the Lyapunov functional is obtained. These results have advantages over some existing ones because the combination of the delay decomposition technique and the reciprocally convex approach. Two examples are provided to demonstrate the less conservatism and effectiveness of the results in this paper.

Recently, a new model of system with two additive time-varying delay components was proposed in [16]. This model has a strong application background in remote control and networked control. Take a state-feedback networked control, for example. Since the physical plant, controller, sensor, and actuator are located at different places, signals are transmitted from one device to another. Thus time delays will appear. Among those delays there are two networkinduced ones, one from sensor to controller and the other from controller to actuator. With the two delays considered, the closed-loop system will appear with two additive time delays in the state. Because of the network transmission conditions, the two delays are generally time-varying with different properties. Therefore it is of significance to consider stability for systems with two additive time-varying delay components. The stability analysis was addressed in [16], and a delay-dependent stability criterion was obtained; it was further improved in [17], where a marginally delayed state was exploited to construct Lyapunov functional and more free weighting matrices were introduced to estimate the upper bound of the derivative of the Lyapunov functional. However, that leaves much room for improvement on the stability criteria in [16,17]. In [18], a new Lyapunov functional is constructed to derive new condition for the two additive time-varying delay systems. This paper makes full use of and any useful terms in the calculation of the time derivative. It is seen that 1 ( ), ( ) − 1 ( ), and ℎ − ( ) are not simply enlarged as ℎ 1 , ℎ − ℎ 1 , and ℎ, respectively. Instead, the relationship of 1 ( )+(ℎ 1 − 1 ( )) = ℎ 1 , (ℎ− ( ))+( ( )− 1 ( )) −(ℎ 1 − 1 ( )) = ℎ − ℎ 1 , and ( ) + (ℎ − ( )) = ℎ is considered. The stability conditions are in form of many linear matrix inequalities in this paper. However, many LMIs caused by a integral representation may bring conservative. Reference [19] presents a less conservative result for stability analysis of continuous-time systems with additive delay by constructing a new Lyapunov-Krasovskii functional and utilizing free matrix variables in approximating certain integral quadratic terms in obtaining the stability condition in terms of linear matrix inequalities. However, it is easy to see that the stability criteria for the given delay bound 2 are good while for the given delay bound 1 are undesirable, compared to some other recent paper. The stabilization for systems with two additive time-varying delays is studied by [20]. Different from 2 The Scientific World Journal [17], the terms 1 1 2 , and (ℎ− ( )) −1 2 are not enlarged roughly but kept as they are and handled using the convex polyhedron method. This paper is less conservative than [16,17]. However, similar to [18], many LMIs may also cause conservativeness. Combining with a reciprocally convex combination technique, the new stability condition is obtained [21]. Different from [16,17,19], the information about ( ), 1 ( ), and 2 ( ) is fully considered in the constructed Lyapunov functional. So far, [21] has presented the best results for delay-dependent stability analysis for delay systems with two additive timevarying delays. In fact, the results provided by [21] are also conservative to some extent, which motivates the study of this paper.
In this paper, the problem of stabilization analysis for continuous-time systems with two additive time-varying delay components is investigated. Firstly, with the idea of delay decomposition, by considering the independence and the variation of two additive time-varying delay components, a new class of Lyapunov functionals is constructed. Combining with a tighter estimation of the derivative of the Lyapunov functional and a reciprocally convex combination technique [22], new delay-dependent stability criteria with less conservatism are derived in terms of linear matrix inequalities (LMIs). Secondly, based on the obtained stability conditions, with the new introduced positive scalar, the controller is designed for the control systems. Finally, two numerical examples are also given to show the effectiveness and the improvement of the proposed method. Notation 1. Throughout this paper, a real symmetric matrix > 0 (≥0) denotes as being a positive definite (positive semidefinite) matrix. is used to denote an identity matrix with proper dimension. Matrices, if not explicitly stated, are assumed to have compatible dimensions. The symmetric terms in a symmetric matrix are denoted by .

Problem Statement
Consider the following time-delay system with two additive time-varying delays: where ( ) ∈ is the state vector, ( ) ∈ is the control input which is arranged as ( ) = ( ). ∈ × , ∈ × , ∈ × , and ∈ × are constant matrices, and ( ) is the initial condition function. The time delays 1 ( ) and 2 ( ) are time-varying differentiable functions that satisfy where 1 , 2 and 1 , 2 are constants. Naturally, we denote In fact, system (1) belongs to a special class of systems with single delay:̇( where ( ) satisfies 0 ≤ ( ) ≤ and( ) ≤ . And when = 0, the system (5) becomeṡ Our purpose of this paper is to study the stabilization for system (1), and the stability of (6) is firstly studied.
To end this section, we introduce the following lemmas, which will play an important role in the proof of the main results.
Lemma 1 (see [2]). For any constant matrix ∈ × , = > 0, and scalar > 0, the vector function : [− , 0] → such that the integrations concerned are well defined; then Lemma 2 (see [22] Our purpose of this paper is to study the stabilization for system (1), and the stability of (6) is firstly studied.

Stability Analysis
The Scientific World Journal 3 where Φ ∈ 12×12 and Ψ ∈ 12×1 are block matrices, such as and the rest of the items of (10) are all zero.
The time derivative of ( ( )) along the trajectory of system (6) is given bẏ 4 The Scientific World Journal With the delay-partitioning approach and by Lemma 1, one can obtain that Now one can note that From Lemma 2 and (12) in Theorem 3, (21) can be given as follow ) .

Remark 4.
In this paper, the information about ( ), 1 ( ), 2 ( ), and 2 + 1 ( ) is fully considered in Lyapunov functional (14). Not only that, but we also consider the information of /2, 1 /2, 2 /2, ( + 1 )/2, and ( + 2 )/2. So the Lyapunov functional in our paper is more general than the existing paper, and the stability criteria in our paper may be more applicable and less conservative.

Remark 5.
It is noted that the delay decomposition is very important to improve the delay-dependent stability results. For example, this novel term 3 ( ( )) is introduced in our Lyapunov functional. Furthermore, some techniques in the process of the computation for the derivative of the constructed Lyapunov functionals also play an important role in reducing conservativeness of our results. So, for example, − ∫ − 1̇( ) 1 1̇( ) is equivalently converted to two parts in (20), which is in concert with the derivative of the 3 ( ( )), Because it would guarantee the quadratic term of ( − 1 /2) is negative in the derivative of ( ( )) for the system. And there are similar settlements in other places.  The Scientific World Journal It is worthwhile to note that convex polyhedral method may bring more conservativeness compared to the reciprocally convex method, because it always generates more than one conditions, which result in many matrices used again and again.

Controller
Design. The approach of Theorem 3 can be used as a useful tool for the stabilization problem of system (1) with ( ) = ( ). Now we are in a position to design the controller by convex optimization approach. , , , , where Φ ∈ 12×12 and Ψ ∈ 12×1 are block matrices, such as Φ 11 = 11 + 11 − 2 1 − 2 3 − 2 5 + 1 and the rest of the items of (31) are all zero. Furthermore, a desired controller gain matrix is given by Proof. When the controller ( ) = ( ), then the closedloop system (1) is formulated as follows: Replace with ( + ) in Theorem 3, and use the Schur complement, (10) can be expressed as With these notations and (36) in mind, performing a congruence transformation to (38) and (11)-(12) by 1 , 2 , and 3 , respectively, and by Schur complements, one can get with where Φ and are defined in Theorem 3. Noting that there exists a positive number such that it is easy to see that Therefore, (31)-(33) hold if (10)- (12) hold. The proof is completed.

Remark 8. It is very important to introduce a positive scalar
to the effectiveness of Theorem 7. It is high load for − to stabilize the five positive definite matrices ( = 1, 2, . . . , 5) stabilized in (39). Therefore, could play an important role in adjusting the computation of LMIs in Theorem 7.

Numerical Examples
In order to show the reduced conservatism and the effectiveness of the approaches presented in this paper, in this section, two numerical examples are provided.
Example 9 (see [21]). Consider the delayed system (6) with We intend to find the upper bound 2 of 2 ( ) when 1 is known and the upper bound 1 of 1 ( ) when 2 is known, below which the system is asymptotically stable; see Table 1. From Table 2, it is easy to see that our proposed stability criterion gives a less conservative result than the one in [16][17][18][19][20][21], when 2 is known, however, our condition is only less conservative than [16][17][18][19][20] when the 1 gets bigger and bigger, such as 1 = 1.2 and 1 = 1.5. So, this leaves much room for improvement on the stability conditions of dynamical systems with two additive time-varying delays. This should be a goal of future studies.
Example 10 (see [21]). Consider the dynamical system (5) with If we set 1 = 1, 2 = 5.334, and = 1/500, it is clear to see that the systems cannot be stable without the controller. However, with the controller, the dynamical systems with two additive time-varying delays can be stabilized. By computing in the MATLAB, we can obtain some matrices as This example shows again that our approach is effective for the stabilization for the control system with two additive time-varying delays.

Conclusion
In this paper, we study the problem of stabilization for delay system with two additive time-varying delays. First of all, the less conservative delay-dependent stability conditions are given by constructing a new Lyapunov functional based on the ideal of delay decomposition, combining the analysis technique of inequalities with the reciprocally convex approach. And then, the controller of the closed-loop system is designed by the transformation technique of inequalities.

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The Scientific World Journal  Finally, two examples are analyzed to show the less conservative than some existing results and the effectiveness of our approach provided in this paper.