Discrete Dynamics in Nature and Society Volume 2008, Article ID 421614, 14 pages doi:10.1155/2008/421614 Research Article Delay-Dependent Exponential Stability for Discrete-Time BAM Neural Networks with Time-Varying Delays Yonggang Chen, 1 Weiping Bi, 2 and Yuanyuan Wu 3 1 Department of Mathematics, Henan Institute of Science and Technology, Xinxiang 453003, China 2 College of Mathematics and Information Science, Henan Normal University, Xinxiang 453007, China 3 Key Laboratory of Measurement and Control of Complex Systems of Engineering, Ministry of Education, School of Automation, Southeast University, Nanjing 210096, China Correspondence should be addressed to Yonggang Chen, happycygzmd@tom.com Received 18 May 2008; Revised 5 August 2008; Accepted 10 September 2008 Recommended by Yong Zhou This paper considers the delay-dependent exponential stability for discrete-time BAM neural networks with time-varying delays. By constructing the new Lyapunov functional, the improved delay-dependent exponential stability criterion is derived in terms of linear matrix inequality LMI. Moreover, in order to reduce the conservativeness, some slack matrices are introduced in this paper. Two numerical examples are presented to show the effectiveness and less conservativeness of the proposed method. Copyright q 2008 Yonggang Chen et al. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. 1. Introduction Bidirectional associative memory BAM neural networks were first introduced by Kosko 1, 2. It generalizes the single-layer autoassociative Hebbian correlator to a two-layer patternmatched heteroassociative circuits. This class of neural networks has been successfully applied to pattern recognition and artificial intelligence. In those applications, it is very important to guarantee the designed neural networks to be stable. On the other hand, time delays are unavoidably encountered in the implementation of neural networks, and its existence will lead to instability, oscillation, and poor performances of neural networks. Therefore, the the asymptotic or exponential stability analysis for BAM neural networks with time delays has received great attention during the past years, see, for example, 3 15. The obtained results are classified into two categories: delay-independent results 3 5, 7, 10 and delay-dependent results 6, 9, 11, 12, 14 16. Generally speaking, the delay-dependent results are less conservative than the delay-independent ones, especially when the size of time delay is small.
2 Discrete Dynamics in Nature and Society It should be pointed out that all of the above-mentioned references are concerned with continuous-time BAM neural networks. However, when implementing the continuous-time neural networks for computer simulation, for experimental or computational purposes, it is essential to formulate a discrete-time system that is an analogue of the continuous-time recurrent neural networks 17. Generally speaking, the stability analysis of continuous-time neural networks is not applicable to the discrete version. Therefore, the stability analysis for various discrete-time neural networks with time delays is widely studied in recent years 17 28. Using M-matrix method, Liang and Cao 25 studied the exponential stability of continuous-time BAM neural network with constant delays and its discrete analogue. Liang et al. 26 also studied the dynamics of discrete-time BAM neural networks with variable time delays based on unreasonably severe constraints on the delay functions. By using the Lyapunov functional method and linear matrix inequality technique, the exponential stability and robust exponential stability for discrete-time BAM neural networks with variable delays were considered in 27, 28, respectively. However, the results presented in 27, 28 are still conservative, since the the Lyapunov functionals constructed in 27, 28 are so simple. Therefore, there is much room to improve the results in 27, 28. In this paper, we present a new exponential stability criterion for discrete-time BAM neural networks with time-varying delays. Compared with the existing methods, the main contributions of this paper are as follows. Firstly, more general Lyapunov functional is employed to obtain the improved exponential stability criterion; secondly, in order to reduce the conservativeness, some slack matrices, which bring much flexibility in solving LMI, are introduced in this paper. The proposed exponential stability criterion is expressed in LMI which can be efficiently solved by LMI toolbox in Matlab. Finally, two numerical examples are presented to show that our result is less conservative than some existing ones 27, 28. The organization of this paper is as follows. Section 2 presents problem formulation of discrete-time BAM neural networks with time delay-varying. In Section 3, our main result of this paper is established and some remarks are given. In Section 4, numerical examples are given to demonstrate the proposed method. Finally, conclusion is drawn in Section 5. Notation Throughout this paper, the erscript T stands for the transpose of a matrix. R n and R n n denote the n-dimensional Euclidean space and set of all n n real matrices, respectively. A real symmetric matrix P>0 0 denotes P being a positive definite positive semidefinite matrix. I is used to denote an identity matrix with proper dimension. For integers a, b, and a<b, N a, b denote the discrete interval N a, b {a, a 1,...,b 1,b}. λ M X and λ m X stand for the maximum and minimum eigenvalues of the symmetric matrix X, respectively. Matrices, if not explicitly stated, are assumed to have compatible dimensions. The symmetric terms in a symmetric matrix are denoted by. 2. Problem formulation Consider the following discrete-time BAM neural network with time-varying delays: m u i k 1 a i u i k w ij fj v j k τ k I i, j 1 n v j k 1 b j v j k v ji g i u i k h k J j, i 1 i 1, 2,...,n, j 1, 2,...,m, 2.1
Yonggang Chen et al. 3 where u i k and v j k are the states of the ith neuron from the neural field F X and the jth neuron from the neural field F Y at time k, respectively; a i,b j 0, 1 denote the stability of internal neuron process on the X-layer and the Y-layer, respectively; w ij,v ji are real constants, and denote the synaptic connection weights; fj g i denote the activation functions of the jth neuron from the neural field F Y and the jth neuron from the neural field F X, respectively; I i and J j denote the external constant inputs from outside the network acting on the ith neuron from the neural field F X and the jth neuron from the neural field F Y, respectively. τ k and h k represent time-varying interval delays satisfying τ m τ k τ M, h m h k h M, 2.2 where τ m,τ M,h m,andh M are positive integers. Throughout this paper, we make the following assumption on the activation functions f j, g i. A1 The activation functions f j, g i i 1, 2,...,n, j 1, 2,...,m are bounded on R. A2 For any ζ 1,ζ 2 R, there exist positive scalars l 1j,l 2i such that 0 f j ζ 1 f j ζ 2 l 1j ζ 1 ζ 2, j 1, 2,...,m, 0 g j ζ 1 g j ζ 2 l 2i ζ 1 ζ 2, i 1, 2,...,n. 2.3 It is clear that under Assumption A1 and A2, system 2.1 has at least one equilibrium. In order to simplify our proof, we shift the equilibrium point u u 1,u 2,...,u n T, v v 1,v 2,...,v m T of system 2.1 to the origin. Let x i k u i k u i,y j k v j k v j,f j y j k f j v j k f j v j,g i x i k g i u i k g i u i, then system 2.1 can be transformed to m x i k 1 a i x i k w ij f j y j t τ k, j 1 n y j k 1 b j y j k v ji g i x i t h k, i 1 i 1, 2,...,n j 1, 2,...,m. 2.4 Obviously, the the activation functions f j, g i satisfy the following conditions. A3 For any ζ R, there exist positive scalars l 1j,l 2i such that 0 f j ζ l 1j ζ, j 1, 2,...,m, 0 g i ζ l 2i ζ, i 1, 2,...,n. 2.5 Also we assume that system 2.4 with initial value x i s φ i s, y j s ψ j s, s N τ, 0, i 1, 2,...,n, j 1, 2,...,m, 2.6 where τ max{τ M,h M }.
4 Discrete Dynamics in Nature and Society For convenience, we rewrite system 2.4 in the form x k 1 Ax k Wf y k τ k, y k 1 By k Vg x k h k, x s φ s, y s ψ s, s N τ, 0, 2.7 where x k x 1 k,x 2 k,...,x n k T, y k y 1 k,y 2 k,...,y m k T, f y k f 1 y 1 k,f 2 y 2 k,...,f m y m k T,g x k g 1 x 1 k,g 2 x 2 k,...,g n x n k T, A diag{a 1,a 2,...,a n }, B diag{b 1,b 2,...,b m }, W w ij m n, V v ij n m,φ s φ 1 s, φ 2 s,...,φ n s T, ψ s ψ 1 s,ψ 2 s,...,ψ m s T. From above analysis, we can see that the exponential stability problem of system 2.1 on equilibrium x is changed into the zero stability problem of system 2.7. Therefore, in the following part, we will devote into the exponential stability analysis problem of system 2.7. Before giving the main result, we will firstly introduce the following definition and lemmas. Definition 2.1. The trivial solution of BAM neural network 2.7 is said to be globally exponentially stable, if there exist scalars r>1andm>1 such that ( x k 2 y k 2 M s N h M,0 φ s 2 s N τ M,0 ψ s 2 )r k. 2.8 Lemma 2.2 see 29. For any real vectors a, b, and any matrix Q>0 with appropriate dimensions, it follows that 2a T b a T Qa b T Q 1 b. 2.9 3. Main result In this section, we are in a position to present the global exponential stability criterion of system 2.7. Theorem 3.1. For given diagonal matrices L 1 diag{l 11,l 12,...,l 1m } and L 2 diag{l 21,l 22,...,l 2n }. Under Assumptions (A1) and (A2), the system 2.7 is globally exponentially stable, if there exist matrices P i > 0, Q i > 0, R i > 0, S i > 0, Z i > 0, i 1, 2, L j,m j,n j, T j, j 1, 2,...,8, and diagonal matrices D 1 diag{d 11,d 12,...,d 1m } > 0, D 2 diag{d 21,d 22,...,d 2n } > 0, such that the following LMI holds: Ω h M L h M h m M τ M N τ M τ m T Z 1 0 0 0 Z 1 0 0 < 0, 3.1 Z 2 0 Z 2
Yonggang Chen et al. 5 where ω 11 ω 12 ω 13 ω 14 ω 15 ω 16 m 1 l t 7 l t 8 ω 22 ω 23 ω 24 ω 25 ω 26 ω 27 t t 8 nt 8 ω 33 t t 4 ω 35 ω 36 m 3 t t 7 t t 8 ω 44 n 4 m 4 l 4 m 4 0 ω ω 55 ω 56 m 5 n t, 7 ω 58 ω 66 ω 67 l t 8 mt 8 ω 77 m t 8 ω 88 l [ t, l t 1 lt 2 lt 3 lt 4 lt 5 lt 6 lt 7 8] lt m [ t, m t 1 mt 2 mt 3 mt 4 mt 5 mt 6 mt 7 8] mt n [ t, n t 1 nt 2 nt 3 nt 4 nt 5 nt 6 nt 7 8] nt t [ t, t t 1 tt 2 tt 3 tt 4 tt 5 tt 6 tt 7 8] tt ω 11 ra t p 1 a r h m h m a i t z 1 a i p 1 h m h m 1 q 1 r 1 l 1 l t 1, ω 12 l t 2 t 1 n 1, ω 13 l t 3 t 1, ω 14 ra t p 1 w r h m h m a i t z 1 w l t 4, ω 15 l t 5 n 1, ω 16 l 1 l t 6 m 1, ω 22 r τ m q 2 t 2 t t 2 d 1 n 2 n t 2, ω 23 t 2 t t 3 nt 3, ω 24 t t 4 nt 4, ω 25 t t 5 n 2 n t 5, ω 26 t t 6 m 2 l 2 n t 6, ω 27 m 2 t t 7 nt 7, ω 33 r τ m r 2 t 3 t t 3, ω 35 n 3 t t 5,
6 Discrete Dynamics in Nature and Society ω 36 m 3 l 3 t t 6, ω 44 rw t p 1 w r h m h m w t z 1 w l 1 1 d 1l 1 1, ω 55 rb t p 2 b r τ m τ m b i t z 2 b i p 2 τ m τ m 1 q 2 r 2 n 5 n t 5, ω 56 m 5 l 5 n t 6, ω 58 rb t p 2 v r τ m τ m b i t z 2 v n t 8, 3.2 ω 66 r h m q 1 l 6 l t 6 d 2 m 6 m t 6, ω 67 l t 7 m 6 m t 7, ω 77 r h m r 1 m 7 m t 7, ω 88 rv t p 2 v r τ m τ m v t z 2 v l 1 2 d 2l 1 2. Proof. Choose the following Lyapunov-Krasovskii candidate function of system 2.7 as follows: V k V 1 k V 2 k V 3 k V 4 k V 5 k, 3.3 where v 1 k r k x t k p 1 x k r k y t k p 2 y k, v 2 k l k h k r l x t l q 1 x l l k τ k r l y t l q 2 y l, v 3 k h m θ h m 1 l k θ r l x t l q 1 x l τ m θ τ m 1 l k θ r l y t l q 2 y l, 3.4 v 4 k r l x t l r 1 x l r l y t l r 2 y l, l k h m l k τ m v 5 k r h m θ h m l k θ r l η t 1 l z 1η 1 l r τ m θ τ m l k θ r l η t 2 l z 2η 2 l, and η 1 l x l 1 x l, η 2 l y l 1 y l.
Yonggang Chen et al. 7 Calculating the difference of V k along the trajectories of system 2.7, we can obtain δv 1 k r k 1 ax k wf y k τ k t p 1 ax k wf y k τ k r k 1 by k vg x k h k t p 2 by k vg x k h k r k x t k p 1 x k r k y t k p 2 y k r k{ x t k ra t p 1 a p 1 x k 2rx t k a t p 1 wf y k τ k rf t y k τ k w t p 1 wf y k τ k y t k rb t p 2 b p 2 y k 2ry t k b t p 2 vg x k h k rg t x k h k v t p 2 vg x k h k }, 3.5 δv 2 k r k x t k q 1 x k r k h k x t k h k q 1 x k h k r k y t k q 2 y k r k τ k y t k τ k q 2 y k τ k k h m l k 1 h k 1 r l x t l q 1 x l k τ m l k 1 τ k 1 r l y t l q 2 y l r k x t k q 1 x k r k h m x t k h k q 1 x k h k r k y t k q 2 y k r k τ m y t k τ k q 2 y k τ k k h m k τ m r l x t l q 1 x l r l y t l q 2 y l, l k 1 h m l k 1 τ m δv 3 k h m h m r k x t k q 1 x k τ m τ m r k y t k q 2 y k k h m k τ m r l x t l q 1 x l r l y t l q 2 y l, l k 1 h m l k 1 τ m δv 4 k r k x t k r 1 x k r k h m x t k h m r 1 x k h m r k y t k r 2 y k r k τ m y t k τ m r 2 y k τ m, δv 5 k r k r h m h m η t 1 k z 1η 1 k r h m l k h m r l η t 1 l z 1η 1 l r k r τ m τ m η t 2 k z 2η 2 k r τ m r l η t 2 l z 2η 2 l l k τ m r k r h m h m a i x k wf y k τ k t z 1 a i x k wf y k τ k r k r τ m τ m b i y k vg x k h k t z 2 b i y k vg x k h k r k r k l k h k l k τ k k h k η t 1 l z 1η 1 l r k k τ k η t 2 l z 2η 2 l r k l k h m η t 1 l z 1η 1 l l k τ m η t 2 l z 2η 2 l. 3.6 3.7 3.8 3.9
8 Discrete Dynamics in Nature and Society By Lemma 2.2, we have l k h k η t 1 l z 1η 1 l 2 l k h k η t 1 l lt ξ k l k h k ξ t k lz 1 1 lt ξ k 2 x t k x t k h k l t ξ k h k ξ t k lz 1 1 lt ξ k ξ t k ψ 1 l t lψ 1 ξ k h m ξ t k lz 1 1 lt ξ k, 3.10 k h k η t 1 l z 1η 1 l 2 l k h m k h k k h k η t 1 l mt ξ k ξ t k mz 1 1 mt ξ k l k h m l k h m 2 x t k h k x t k h m m t ξ k h m h k ξ t k mz 1 1 mt ξ k ξ t k ψ 2 m t mψ 2 ξ k h m h m ξ t k mz 1 1 mt ξ k, 3.11 l k τ k η t 2 l z 2η 2 l 2 l k τ k η t 2 l nt ξ k l k τ k ξ t k nz 1 2 nt ξ k 2 y t k y t k τ k n t ξ k τ k ξ t k nz 1 2 nt ξ k ξ t k ψ 3 n t nψ 3 ξ k τ m ξ t k nz 1 2 nt ξ k, 3.12 k τ k η t 2 l z 2η 2 l 2 l k τ m k τ k k τ k η t 2 l tt ξ k ξ t k tz 1 2 tt ξ k l k τ m l k τ m 2 y t k τ k y t k τ m t t ξ k τ m τ k ξ t k tz 1 2 tt ξ k ξ t k ψ 4 t t tψ 4 ξ k τ m τ m ξ t k tz 1 2 tt ξ k, 3.13 where l [ t, l t 1 lt 2 lt 3 lt 4 lt 5 lt 6 lt 7 8] lt m [ t, m t 1 mt 2 mt 3 mt 4 mt 5 mt 6 mt 7 8] mt n [ t, n t 1 nt 2 nt 3 nt 4 nt 5 nt 6 nt 7 8] nt t [ t, t t 1 tt 2 tt 3 tt 4 tt 5 tt 6 tt 7 8] tt ψ 1 [ i 0 0 0 0 i 0 0 ] t, 3.14 ψ 2 [ 0 0 0 0 0 i i 0 ] t, ψ 3 [ 0 i 0 0 i 0 0 0 ] t, ψ 4 [ 0 i i 0 0 0 0 0 ] t,
Yonggang Chen et al. 9 and ξ k x T k y T k τ k y T k τ M f T y k τ k y T k x T k h k x T k h M g T x k h k. By inequalities 2.5, it is well known that there exist positive diagonally matrices D i 0 i 1, 2 such that the following inequalities hold: r k[ y t t τ t d 1 y t τ t f t y t τ t l 1 1 d 1l 1 1 f y t τ t ] 0, r k[ x t t h t d 2 x t h t g t x t h t l 1 2 d 2l 1 2 g x t h t ] 0, 3.15 where L 1 diag{l 11,l 12,...,l 1m }, L 2 diag{l 21,l 22,...,l 2n }. Substituting 3.10 3.13 into 3.9, we have δv k δv 1 k δv 2 k δv 3 k δv 4 k δv 5 k r k[ y t t τ t d 1 y t τ t f t y t τ t l 1 1 d 1l 1 1 f y t τ t ] r k[ x t t h t d 2 x t h t g t x t h t l 1 2 d 2l 1 2 g x t h t ] r k ξ t k [ ω h m lz 1 1 lt h m h m mz 1 1 mt τ m nz 1 2 nt τ m τ m tz 1 ] 2 tt ξ k, 3.16 where Ω, L,M,N,and T are defined in Theorem 3.1. Thus, if LMI 3.1 holds, it can be concluded that ΔV k < 0 according to Schur complement, which implies that V k <V 0. Note that v 1 0 x t 0 p 1 x 0 y t 0 p 2 y 0 v 2 0 v 3 0 λ m p 1 l h 0 s n h m,0 r l x t l q 1 x l λ m q 1 1 r h m h m θ h m 1 l θ φ s 2 λ m p 2 l τ 0 s n h m,0 r l x t l q 1 x l s n τ m,0 r l y t l q 2 y l ψ s 2, φ s 2 λ m q 2 1 r τ m τ m θ τ m 1 l θ r l y t l q 2 y l s n τ m,0 h m h m r l x t l q 1 x l τ m τ m r l y t l q 2 y l l h m l τ m h m h m λ m q 1 1 r h m s n h m,0 ψ s 2 ψ s 2, 3.17 3.18 3.19 τ m τ m λ m q 2 1 r τ m ψ s 2, s n τ m,0
10 Discrete Dynamics in Nature and Society v 4 0 r l x t l r 1 x l r l y t l r 2 y l l h m l τ m λ m r 1 1 r h m s n h m,0 φ s 2 λ m r 2 1 r τ m s n τ m,0 ψ s 2, 3.20 v 5 0 r h m θ h m l θ r l η t 1 l z 1η 1 l r τ m θ τ m l θ 1 r l η t 2 l z 2η 2 l r h m h m λ m z 1 r l η t 1 l η 1 l r τ m τ m λ m z 2 r l η t 2 l η 2 l l h m l τ m r h m h m λ m z 1 1 r h m s n h m, 1 η 1 s 2 3.21 r τ m τ m λ m z 2 1 r τ m s n τ m, 1 η 2 s 2, η 1 s 2 x s 1 x s 2 s n h m, 1 s n h m, 1 2 x s 1 2 x s 2 s n h m, 1 3.22 4 s n h m,0 φ s 2, η 2 s 2 y s 1 y s 2 s n τ m, 1 s n τ m, 1 2 y s 1 2 y s 2 s n τ m, 1 3.23 4 ψ s 2. s n τ m,0 Substituting 3.22, 3.23 into 3.21, and combining 3.17 3.21, then we have V 0 5 V i 0 ρ 1 i 1 φ s 2 ρ 2 ψ s 2, s N h M,0 s N τ M,0 3.24 where ρ 1 λ m p 1 [ h m h m 1 λ m q 1 λ m r 1 4r h m h m λ m z 1 ]1 r h m, ρ 2 λ m p 2 [ τ m τ m 1 λ m q 2 λ m r 2 4r τ m τ m λ m z 2 ]1 r τ m. 3.25
Yonggang Chen et al. 11 On the other hand, V k r k x T k P 1 x k r k y T k P 2 y k r k{ λ m P 1 x k 2 λ m P 2 y k 2}. 3.26 Therefore, we can obtain x k 2 y k 2 α β ( s N h M,0 φ s 2 s N τ M,0 ψ s 2 )r k, 3.27 where α max{ρ 1,ρ 2 },β min{λ m P 1,λ m P 2 }. Obviously, α/β > 1, by Definition 2.1, the system 2.7 or 2.1 is globally exponentially stable. Remark 3.2. Based on the linear matrix inequality LMI technique and Lyapunov stability theory, the exponential stability for discrete-time delayed BAM neural network 2.1 was investigated in 26 28. However, it should be noted that the results in 26 are based on the unreasonably severe constraints on the delay functions 1 <τ k 1 < 1 τ k, 1 <h k 1 < 1 h k, and the results in 27, 28 are based on the simple Lyapunov functionals. In this paper, in order to obtain the less conservative stability criterion, the novel Lyapunov functional V k is employed, which contains V 4 k, V 5 k, and more general than the traditional ones 26 28. Moreover, some slack matrices, which bring much flexibility in solving LMI, are introduced in this paper. Remark 3.3. By setting r 1inTheorem 3.1, we can obtain the global asymptotic stability criterion of discrete-time BAM neural network 2.7. Remark 3.4. Theorem 3.1 in this paper depends on both the delay upper bounds τ M,h M and the delay intervals τ M τ m and h M h m. Remark 3.5. The proposed method in this paper can be generalized to more complex neural networks, such as delayed discrete-time BAM neural networks with parameter uncertainties 30, 31 and stochastic perturbations 30 32, delayed interval discrete-time BAM neural networks 28, and discrete-time analogues of BAM neural networks with mixed delays 32, 33. 4. Numerical examples Example 4.1. Consider the delayed discrete-time BAM neural network 2.7 with the following parameters: A [ ] [ ] 0.8 0 0.5 0, B, W 0 0.9 0 0.4 [ ] [ ] 0.1 0.01 0.15 0, V. 4.1 0.2 0.1 0.2 0.1 The activation functions satisfy Assumptions A1 and A2 with L 1 [ ] 1 0, L 0 1 2 [ ] 1 0. 4.2 0 1
12 Discrete Dynamics in Nature and Society Table 1: Maximum allowable delay bounds for Example 4.1. τ m h m 2 4 6 8 10 15 20 25 τ M h M 27, 28 6 8 10 12 14 19 24 29 τ M h M Theorem 3.1 11 12 13 15 16 21 25 30 For this example, by Theorem 3.1 in this paper with r 1, we can obtain some maximum allowable delay bounds for guaranteeing the asymptotic stability of this system. For a comparison with 27, Theorem 1 and in 28, Corollary 1, we made Table 1. For this example, it is obvious that our result is less conservative than those in 27, 28. Example 4.2 see 27. Consider the delayed discrete-time BAM NN 2.7 with the following parameters: 1 A 5 0 0 1, 5 1 B 10 0 0 1 10, W 0 1 8 1, 8 0 V 1 20 0 0 1 20. 4.3 The activation functions satisfy Assumptions A1 and A2 with L 1 [ ] 1 0, L 0 1 2 [ ] 1 0. 4.4 0 1 Now, we assume τ k h k 4 2sin π/2 k, r 1.55. It is obvious that 2 τ k h k 6, that is, h m τ m 2, h M τ m 6. In this case, it is found that the exponential conditions proposed in 27, 28 is not satisfied. However, it can be concluded that this system is globally exponentially stable by using Theorem 3.1 in this paper. If we assume h m τ m τ M 2, r 2.7. Using 27, Theorem 1 and 28, Corollary 1, the achieved maximum allowable delays for guaranteeing the globally exponentially stable of this system are h M 3, h M 3, respectively. However, we can obtain the delay bound h M 4byusing Theorem 3.1 in this paper. For this example, it is seen that our result improve some existing results 27, 28. 5. Conclusion In this paper, we consider the delay-dependent exponential stability for discrete-time BAM neural networks with time-varying delays. Based on the Lyapunov stability theory and linear matrix inequality technique, the novel delay-dependent stability criterion is obtained. Two numerical examples show that the proposed stability condition in this paper is less conservative than previously established ones. Acknowledgments The authors would like to thank the Associate Editor and the anonymous reviewers for their constructive comments and suggestions to improve the quality of the paper. This work was ported by the National Natural Science Foundation of China no. 60643003 and the Natural Science Foundation of Henan Education Department no. 2007120005.
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