1. 引言

时滞神经网络的稳定性问题是神经网络处理联想记忆、信号处理和一些优化问题等多个实际问题的基础 [1] [2] [3]。一方面，在应用神经网络之前，应确保稳定性；另一方面，在神经网络的实现中，由于神经元的有限切换速率就不可避免的出现时滞，很多相关研究表明时滞会导致不良的动态行为，这些行为会使得系统的性能下降甚至不稳定 [4]，因此研究时滞神经网络的稳定性是非常有意义的。

到目前为止，学者们针对时滞神经网络系统的稳定性研究主要采用Lyapunov泛函方法。通过利用Lyapunov稳定性理论 [5]，构造恰当的Lyapunov泛函以及尽可能精细地估计泛函的导数来得到低保守性的稳定性准则。对于构造Lyapunov泛函方法，目前比较常见的有构造带有增广的Lyapunov泛函 [6]，利用时滞分割方法构造泛函 [7] 以及构造带有多重积分项的泛函 [8]。对于估计泛函的导数，主要是估计求导后产生的积分项，力求获得求导后更严格的上界。为了处理这些积分，学者们主要通过不等式放缩的方法，例如Jensen不等式 [9]，基于Wirtinger的积分不等式 [10]，基于自由矩阵的积分不等式 [11]，改进的自由矩阵积分不等式 [12] 以及互凸不等式 [13] 等等。这些不等式有效地降低了时滞神经网络的时滞依赖稳定性条件，不过仍然有改进的空间。

文献 [14] 中通过引入增广的Lyapunov泛函并应用于Wirtinger不等式中，得到了保守性较低的时滞相关稳定性标准，文献 [15] 利用零等式改进具有增广的一重积分不等式，与直接使用Jensen不等式放缩相比，运用零等式可以巧妙加入自由矩阵，从而提供更大的自由度进而得到更紧的时滞上界。然而，文献 [15] 中不等式的放缩只带有一重积分信息，具有一定的保守性。众所周知，高阶积分项在降低时滞系统的保守性中扮演着十分重要的作用，例如在估计一重积分不等式中引入二重积分项，这时二重积分状态信息会与一重状态信息以及系统的状态信息交叉，从而得到更大的时滞上界，因此建立一个新的带有自由矩阵和二重积分项的具有增广的一重积分不等式对降低时滞神经网络系统的保守性具有深远的意义。此外，值得一提的是在增广向量中引入s相关项能有效克服条件的保守性，因为它将一重积分放入增广向量中并把这个增广向量放入带有一重积分的Lyapunov泛函中，在对这个泛函求导后能够获得更多状态信息。因此，本文拟通过新的积分不等式处理技巧结合更符合系统的Lyapunov泛函，获得保守性更低的稳定性条件。

为了简化表述，我们有必要做如下的符号说明： $R^n$ 表示n维欧式空间； $R^{n\times m}$ 代表 $n\times m$ 的矩阵； $\text{sym}\left\{X\right\}=X+X^{\text{T}}$ ； $\text{diag}\{\cdots \}$ 表示对角矩阵； $\text{col}\{\cdots \}$ 列向量 $X^{\text{T}}$，和 $X^{-1}$ 分别矩阵的转置和逆矩阵； $*$ 表示矩阵的对称项。

2. 预备知识

2.1. 系统描述

考虑一般的带有时变时滞的神经网络系统

$\{\begin{array}{l}\stackrel{\dot{}}{x}\left(t\right)=-Ax\left(t\right)+W_{1}f\left(W_{0}x\left(t\right)\right)+W_{2}f\left(W_{0}x\left(t-h\left(t\right)\right)\right),\\ x\left(\theta \right)=\varphi \left(\theta \right),\theta \in \left[-h,0\right].\end{array}$ (1)

其中 $x\left(t\right)\in R^n$ 是系统的状态向量 $A\in R^{n\times n}$， $W_0\in R^{n\times n}$， $W_1\in R^{n\times n}$，和 $W_2\in R^{n\times n}$ 是已知的实数矩阵，初始条件 $\phi \left(\theta \right)$ 是连续的微分函数，h和u是已知的常数，且满足如下条件：

$0<h\left(t\right)<h$, $\stackrel{\dot{}}{h}\left(t\right)<u$. (2)

$f\left(W_{0}x\left(t\right)\right)=\text{col}\left\{f\left(W_{01}x\left(t\right)\right),f\left(W_{02}x\left(t\right)\right),\cdots ,f\left(W_{0n}x\left(t\right)\right)\right\}$ 是神经元的激活函数 $W_{0i}$ 是 $W_0$ 的第i行，假设 $f\left(0\right)=0$ 且满足Lipschitz条件

$l_i^{-}\le \frac{f_i\left(a\right)-f_i\left(b\right)}{a-b}\le l_i^{+}$, (3)

其中， $l_i^{-}$ 和 $l_i^{+}$ 是一些常数，且 $L^{-}=\text{diag}\left\{l_1^{-},l_2^{-},\cdots ,l_n^{-}\right\}$， $L^{+}=\text{diag}\left\{l_1^{+},l_2^{+},\cdots ,l_n^{+}\right\}$。

2.2. 引理

在分析系统(1)的时滞依赖稳定性判据之前，本节首先引入如下一些重要的引理：

引理1. [16] 给定一个二次函数 $f\left(y\right)=a_2{y}^2+a_{1}y+a_0$，当 $\beta \in \left[0,1\right]$ 时，如果有

$T_i=f\left(h_i\right)<0\left(i=1,2\right)$, $T_3=-{\beta }^2{h}_{12}^2{a}_2+f\left(h_1\right)<0$, $T_4=-{\left(1-\beta \right)}^2{h}_{12}^2{a}_2+f\left(h_2\right)<0$,

那么 $f\left(y\right)<0\left(h_1\le y\le h_2\right)$ 成立，其中 $h_{12}=h_2-h_1$。

引理2. [12] 设 $w\left(t\right)$ 是一个可微函数： $\left[a,b\right]\to R^n$，那么存在对称正定矩阵 $H\in R^{n\times n}$，对于任意具有恰当维度的矩阵L，M，有下列的不等式成立：

${\displaystyle {\int }_a^b{\stackrel{\dot{}}{w}}^{\text{T}}\left(s\right)H\stackrel{\dot{}}{w}\left(s\right)\text{d}s}\ge -\text{sym}\left\{{\sigma }_0^{\text{T}}L{\sigma }_1+{\sigma }_0^{\text{T}}M{\sigma }_2\right\}-\left(b-a\right){\sigma }_0^{\text{T}}\left(\frac{3L{H}^{-1}{L}^{\text{T}}+M{H}^{-1}{M}^{\text{T}}}{3}\right){\sigma }_0$

其中 ${\sigma }_1=x\left(b\right)-x\left(a\right)$， ${\sigma }_2=x\left(b\right)+x\left(a\right)-\frac{2}{b-a}{\displaystyle {\int }_a^{b}x\left(s\right)\text{d}s}$， ${\sigma }_0$ 是任意向量。

引理3. [17] 若对称正定矩阵 $R>0$， $x\left(t\right)$ 是一个可微函数： $\left[a,b\right]\to R^n$，则下列不等式成立

${\displaystyle {\int }_a^b{x}^{\text{T}}\left(s\right)Rx\left(s\right)\text{d}s}\ge \frac{1}{b-a}{\left({\displaystyle {\int }_a^{b}x\left(s\right)\text{d}s}\right)}^{\text{T}}R\left({\displaystyle {\int }_a^{b}x\left(s\right)\text{d}s}\right)+\frac{3}{b-a}{\Omega }_1^{\text{T}}R{\Omega }_1$,

${\displaystyle {\int }_a^b{\stackrel{\dot{}}{x}}^{\text{T}}\left(s\right)R\stackrel{\dot{}}{x}\left(s\right)\text{d}s}\ge \frac{1}{b-a}{\Omega }_2^{\text{T}}R{\Omega }_2+\frac{3}{b-a}{\Omega }_3^{\text{T}}R{\Omega }_3$,

其中

${\Omega }_1={\displaystyle {\int }_a^{b}x\left(s\right)\text{d}s}-\frac{2}{b-a}{\displaystyle {\int }_a^b{\displaystyle {\int }_{\beta }^{b}x\left(s\right)\text{d}s\text{d}\beta }}$, ${\Omega }_2=x\left(b\right)-x\left(a\right)$, ${\Omega }_3=x\left(b\right)+x\left(a\right)-\frac{2}{b-a}{\displaystyle {\int }_a^{b}x\left(s\right)\text{d}s}$.

为了能得到保守性更低的稳定性条件，本文首先引入一个改进的一重积分不等式如下：

引理4. 若半正定对称矩阵 $Y_i\in R^{n\times n}\left(i=1,3\right)$， $X_i\in R^{n\times n}\left(i=1,2\right)$，任意矩阵 $Y_2\in R^{n\times n}$， $X_3\in R^{n\times n}$， $X_4\in R^{2n\times 2n}$， $x\left(t\right)$ 是一个可微函数： $\left[a,b\right]\to R^n$，满足：

${\Omega }_0=\left[\begin{array}{cc}{Y}_1& Y_2\\ *& Y_3\end{array}\right]\ge 0$, ${\Omega }_1=\left[\begin{array}{cc}{Y}_1& Y_2+X_1\\ *& Y_3\end{array}\right]\ge 0$, ${\Omega }_2=\left[\begin{array}{cc}{Y}_1& Y_2+X_2\\ *& Y_3\end{array}\right]\ge 0$,

${\Omega }_3=\left[\begin{array}{cc}{Y}_3& X_3\\ *& Y_3\end{array}\right]\ge 0$, ${\Omega }_4=\left[\begin{array}{cc}{\Omega }_1& X_4\\ *& {\Omega }_2\end{array}\right]\ge 0$,

那么，对任意向量 $c\in \left[a,b\right]$，有下面的不等式成立

$\Phi =-{\displaystyle {\int }_a^b{W}^{\text{T}}\left(s\right){\Omega }_{0}W\left(s\right)\text{d}s}\le {\xi }^{\text{T}}\Omega \xi$. (4)

其中

$W\left(s\right)=\text{col}\left\{x\left(s\right),\stackrel{\dot{}}{x}\left(s\right)\right\}$, $\xi =\text{col}\left\{x\left(b\right),x\left(c\right),x\left(a\right),w_1,w_2,v_1,v_2\right\}$, $w_1=\frac{1}{b-c}{\displaystyle {\int }_c^{b}x\left(s\right)\text{d}s}$,

$w_2=\frac{1}{c-a}{\displaystyle {\int }_a^{c}x\left(s\right)\text{d}s}$, $v_1=\frac{1}{b-c}{\displaystyle {\int }_c^b{\displaystyle {\int }_{\theta }^{b}x\left(s\right)\text{d}s\text{d}\theta }}$, $v_2=\frac{1}{c-a}{\displaystyle {\int }_a^c{\displaystyle {\int }_{\theta }^{c}x\left(s\right)\text{d}s\text{d}\theta }}$,

$e_i=\left[\begin{array}{ccc}{0}_{n,\left(i-1\right)n}& I_n& 0_{n,\left(7-i\right)n}\end{array}\right]\left(i=1,2,\cdots ,7\right)$, ${\zeta }_1=\text{col}\left\{e_1-e_2,e_2-e_3\right\}$,

${\zeta }_2=\text{col}\left\{\left(b-c\right)e_4-2e_6,2e_4-e_1-e_2,\left(c-a\right)e_5-2e_7,2e_5-e_2-e_3\right\}$,

$\begin{array}{c}\Omega =\text{sym}\left\{-e_4^{\text{T}}\left(Y_2+X_1\right)\left(e_1-e_2\right)-e_5^{\text{T}}\left(Y_2+X_2\right)\left(e_2-e_3\right)\right\}-\left(b-c\right)e_4^{\text{T}}{Y}_1{e}_4-\left(c-a\right)e_5^{\text{T}}{Y}_1{e}_5\\ -e_2^{\text{T}}\left(X_1-X_2\right)e_2+e_1^{\text{T}}{X}_1{e}_1-e_3^{\text{T}}{X}_2{e}_3-\frac{1}{b-a}{\zeta }_1^{\text{T}}{\Omega }_3{\zeta }_1-\frac{1}{b-a}{\zeta }_2^{\text{T}}{\Omega }_4{\zeta }_2\end{array}$.

证明：对于半正定对称矩阵 $X_i\in R^{n\times n}\left(i=1,2\right)$，有下面的零等式成立

$0=-2{\displaystyle {\int }_c^b{x}^{\text{T}}\left(s\right)X_1\stackrel{\dot{}}{x}\left(s\right)\text{d}s}+x^{\text{T}}\left(b\right)X_{1}x\left(b\right)-x^{\text{T}}\left(c\right)X_{1}x\left(c\right)$,

$0=-2{\displaystyle {\int }_a^c{x}^{\text{T}}\left(s\right)X_2\stackrel{\dot{}}{x}\left(s\right)\text{d}s}+x^{\text{T}}\left(c\right)X_{2}x\left(c\right)-x^{\text{T}}\left(a\right)X_{2}x\left(a\right)$.

将上面两个零等式加入二重积分，合并同类项后可以得到

$\begin{array}{c}\Phi =-{\displaystyle {\int }_a^b{W}^{\text{T}}\left(s\right){\Omega }_{0}W\left(s\right)\text{d}s}-2{\displaystyle {\int }_c^b{x}^{\text{T}}\left(s\right)X_1\stackrel{\dot{}}{x}\left(s\right)\text{d}s}-2{\displaystyle {\int }_a^c{x}^{\text{T}}\left(s\right)X_2\stackrel{\dot{}}{x}\left(s\right)\text{d}s}\\ -x^{\text{T}}\left(c\right)\left(X_1-X_2\right)x\left(c\right)+x^{\text{T}}\left(b\right)X_{1}x\left(b\right)-x^{\text{T}}\left(a\right)X_{2}x\left(a\right)\\ =-{\displaystyle {\int }_c^b{W}^{\text{T}}\left(s\right){\Omega }_{1}W\left(s\right)\text{d}s}-{\displaystyle {\int }_a^c{W}^{\text{T}}\left(s\right){\Omega }_{2}W\left(s\right)\text{d}s}-x^{\text{T}}\left(c\right)\left(X_1-X_2\right)x\left(c\right)\\ +x^{\text{T}}\left(b\right)X_{1}x\left(b\right)-x^{\text{T}}\left(a\right)X_{2}x(\; a\; )\end{array}$

利用引理3中的不等式放缩，展开计算如下

$\begin{array}{c}\Phi \le -\frac{1}{b-c}{\left({\displaystyle {\int }_c^{b}W\left(s\right)\text{d}s}\right)}^{\text{T}}{\Omega }_1\left({\displaystyle {\int }_c^{b}W\left(s\right)\text{d}s}\right)-\frac{1}{c-a}{\left({\displaystyle {\int }_a^{c}W\left(s\right)\text{d}s}\right)}^{\text{T}}{\Omega }_2\left({\displaystyle {\int }_a^{c}W\left(s\right)\text{d}s}\right)\\ -\frac{3}{b-c}{\left({\displaystyle {\int }_c^{b}W\left(s\right)\text{d}s}-\frac{2}{b-c}{\displaystyle {\int }_c^b{\displaystyle {\int }_{\beta }^{b}W\left(s\right)\text{d}s\text{d}\beta }}\right)}^{\text{T}}{\Omega }_1\left({\displaystyle {\int }_c^{b}W\left(s\right)\text{d}s}-\frac{2}{b-c}{\displaystyle {\int }_c^b{\displaystyle {\int }_{\beta }^{b}W\left(s\right)\text{d}s\text{d}\beta }}\right)\\ -\frac{3}{c-a}{\left({\displaystyle {\int }_a^{c}W\left(s\right)\text{d}s}-\frac{2}{c-a}{\displaystyle {\int }_a^c{\displaystyle {\int }_{\beta }^{c}W\left(s\right)\text{d}s\text{d}\beta }}\right)}^{\text{T}}{\Omega }_2\left({\displaystyle {\int }_a^{c}W\left(s\right)\text{d}s}-\frac{2}{c-a}{\displaystyle {\int }_a^c{\displaystyle {\int }_{\beta }^{c}W\left(s\right)\text{d}s\text{d}\beta }}\right)\\ -x^{\text{T}}\left(c\right)\left(X_1-X_2\right)x\left(c\right)+x^{\text{T}}\left(b\right)X_{1}x\left(b\right)-x^{\text{T}}\left(a\right)X_{2}x(\; a\; )\end{array}$

$\begin{array}{l}=-\left(b-c\right)w_1^{\text{T}}{Y}_1{w}_1-2w_1^{\text{T}}\left(Y_2+X_1\right)\left(x\left(b\right)-x\left(c\right)\right)-\frac{1}{b-c}{\left(x\left(b\right)-x\left(c\right)\right)}^{\text{T}}{Y}_3\left(x\left(b\right)-x\left(c\right)\right)\\ -\left(c-a\right)w_2^{\text{T}}{Y}_1{w}_2-2w_2^{\text{T}}\left(Y_2+X_2\right)\left(x\left(c\right)-x\left(a\right)\right)-\frac{1}{c-a}{\left(x\left(c\right)-x\left(a\right)\right)}^{\text{T}}{Y}_3\left(x\left(c\right)-x\left(a\right)\right)\\ -\frac{3}{b-c}{\left[\begin{array}{c}\left(b-c\right)w_1-2v_1\\ 2w_1-x\left(b\right)-x\left(c\right)\end{array}\right]}^T\left[\begin{array}{cc}{Y}_1& Y_2+X_1\\ *& Y_3\end{array}\right]\left[\begin{array}{c}\left(b-c\right)w_1-2v_1\\ 2w_1-x\left(b\right)-x\left(c\right)\end{array}\right]\\ -\frac{3}{c-a}{\left[\begin{array}{c}\left(c-a\right)w_2-2v_2\\ 2w_2-x\left(c\right)-x\left(a\right)\end{array}\right]}^T\left[\begin{array}{cc}{Y}_1& Y_2+X_2\\ *& Y_3\end{array}\right]\left[\begin{array}{c}\left(c-a\right)w_2-2v_2\\ 2w_2-x\left(c\right)-x\left(a\right)\end{array}\right]\\ -x^{\text{T}}\left(c\right)\left(X_1-X_2\right)x\left(c\right)+x^{\text{T}}\left(b\right)X_{1}x\left(b\right)-x^{\text{T}}\left(a\right)X_{2}x(\; a\; )\end{array}$

利用交互凸组合不等式可得

$\begin{array}{c}\Phi \le -\left(b-c\right)w_1^{\text{T}}{Y}_1{w}_1-2w_1^{\text{T}}\left(Y_2+X_1\right)\left(x\left(b\right)-x\left(c\right)\right)-\left(c-a\right)w_2^{\text{T}}{Y}_1{w}_2\\ -2w_2^{\text{T}}\left(Y_2+X_2\right)\left(x\left(c\right)-x\left(a\right)\right)-x^{\text{T}}\left(c\right)\left(X_1-X_2\right)x\left(c\right)+x^{\text{T}}\left(b\right)X_{1}x\left(b\right)\\ -x^{\text{T}}\left(a\right)X_{2}x\left(a\right)-\frac{1}{b-a}{\left[\begin{array}{c}x\left(b\right)-x\left(c\right)\\ x\left(c\right)-x\left(a\right)\end{array}\right]}^{\text{T}}\left[\begin{array}{cc}{Y}_3& X_3\\ *& Y_3\end{array}\right]\left[\begin{array}{c}x\left(b\right)-x\left(c\right)\\ x\left(c\right)-x\left(a\right)\end{array}\right]\\ -\frac{3}{b-a}{\left[\begin{array}{c}\left(b-c\right)w_1-2v_1\\ 2w_1-x\left(b\right)-x\left(c\right)\\ \left(c-a\right)w_2-2v_2\\ 2w_2-x\left(c\right)-x\left(a\right)\end{array}\right]}^{\text{T}}\left[\begin{array}{cc}{\Omega }_1& X_4\\ *& {\Omega }_2\end{array}\right]\left[\begin{array}{c}\left(b-c\right)w_1-2v_1\\ 2w_1-x\left(b\right)-x\left(c\right)\\ \left(c-a\right)w_2-2v_2\\ 2w_2-x\left(c\right)-x\left(a\right)\end{array}\right]\\ ={\xi }^{\text{T}}\Omega \xi \end{array}$

结论成立，证毕。

3. 理论结果及证明

在本节当中，基于上面提到的一重积分不等式引理以及广义的自由矩阵积分不等式引理，我们通过恰当地构造Lyapunov泛函分析得到关于系统(1)的新的时滞依赖条件。

为了简化向量和矩阵表示给出以下术语：

${\varpi }_1\left(t\right)=\frac{1}{h\left(t\right)}{\displaystyle {\int }_{t-h\left(t\right)}^{t}x\left(s\right)\text{d}s}$, ${\varpi }_2\left(t\right)=\frac{1}{t-h\left(t\right)}{\displaystyle {\int }_{t-h}^{t-h\left(t\right)}x\left(s\right)\text{d}s}$, ${\vartheta }_1\left(t\right)=\frac{1}{h\left(t\right)}{\displaystyle {\int }_{t-h\left(t\right)}^t{\displaystyle {\int }_{\theta }^{t}x\left(s\right)\text{d}s\text{d}\theta }}$,

${\vartheta }_2\left(t\right)=\frac{1}{t-h\left(t\right)}{\displaystyle {\int }_{t-h}^{t-h\left(t\right)}{\displaystyle {\int }_{\theta }^{t-h\left(t\right)}x\left(s\right)\text{d}s\text{d}\theta }}$, ${\eta }_2\left(t\right)=\text{col}\left\{x\left(t\right),\stackrel{\dot{}}{x}\left(t\right),f\left(W_{0}x\left(t\right)\right)\right\}$,

${\eta }_1\left(t,s\right)=\text{col}\left\{x\left(s\right),\stackrel{\dot{}}{x}\left(s\right),f\left(W_{0}x\left(s\right)\right),x\left(t\right),x\left(t-h\right),{\displaystyle {\int }_s^{t}x\left(\theta \right)\text{d}\theta }\right\}$, ${\eta }_3\left(t\right)=\text{col}\left\{x\left(t\right),\stackrel{\dot{}}{x}\left(t\right)\right\}$,

${\xi }_1\left(t\right)=\text{col}\left\{x\left(t\right),x\left(t-h\right),{\varpi }_1\left(t\right),{\vartheta }_1\left(t\right),{\displaystyle {\int }_{t-h}^{t}x\left(s\right)\text{d}s},{\displaystyle {\int }_{t-h\left(t\right)}^{t}f\left(W_{0}x\left(s\right)\right)\text{d}s},{\displaystyle {\int }_{t-h}^{t}f\left(W_{0}x\left(s\right)\right)\text{d}s}\right\}$,

$\begin{array}{l}\xi \left(t\right)=\text{col}\{x\left(t\right),x\left(t-h\left(t\right)\right),x\left(t-h\right),{\varpi }_1\left(t\right),{\varpi }_2\left(t\right),{\vartheta }_1\left(t\right),{\vartheta }_2\left(t\right),\stackrel{\dot{}}{x}\left(t-h\left(t\right)\right),\stackrel{\dot{}}{x}\left(t-h\right),{}_{{}_{}{}^{}}{}^{}\\ f\left(W_{0}x\left(t\right)\right),f\left(W_{0}x\left(t-h\left(t\right)\right)\right),{\displaystyle {\int }_{t-h\left(t\right)}^{t}f\left(W_{0}x\left(s\right)\right)\text{d}s},{\displaystyle {\int }_{t-h}^{t-h\left(t\right)}f\left(W_{0}x\left(s\right)\right)\text{d}s}\}\end{array}$,

$g_{i1}\left(s\right)=f_i\left(s\right)-l_i^{-}s$, $g_{i2}\left(s\right)=l_i^{+}s-f_i\left(s\right)$.

定理1 对于给定的实数h和u，若存在对称正定矩阵 $P\in R^{7n\times 7n}$， $Q_1\in R^{5n\times 5n}$， $Q_2\in R^{5n\times 5n}$， $R\in R^{3n\times 3n}$， $Z=\left[\begin{array}{cc}{Z}_1& Z_2\\ *& Z_3\end{array}\right]\in R^{2n\times 2n}$， $N_i\in R^{n\times n}\left(i=1,2\right)$，半正定对角矩阵 $T_{12}\in R^{n\times n}$， $T_{13}\in R^{n\times n}$， $T_{23}\in R^{n\times n}$， $V_k\in R^{n\times n}\left(k=1,2,3,4\right)$， $D_i\in R^{n\times n}$ 任意矩阵 $M_k\in R^{n\times n}$， $S_1\in R^{3n\times 3n}$， $S_2\in R^{n\times n}$， $S_3\in R^{2n\times 2n}$ 得下列线性矩阵不等式成立

${\Gamma }_m=\left[\begin{array}{cc}{Z}_1& Z_2+N_i\\ *& Z_3\end{array}\right]>0\left(m=1,2\right)$, ${\Gamma }_3=\left[\begin{array}{cc}{Z}_3& S_2\\ *& Z_3\end{array}\right]>0$， ${\Gamma }_4=\left[\begin{array}{cc}{\Gamma }_1& S_3\\ *& {\Gamma }_2\end{array}\right]>0$,(5)

${\Gamma }_5=\left[\begin{array}{cc}R& S_1\\ *& R\end{array}\right]>0$, (6)

${\Gamma }_6\left(h\left(t\right)=0\right)={\left({\delta }^{\perp }\right)}^{\text{T}}\left[\begin{array}{ccc}\Xi & \sqrt{h}{M}_3& \sqrt{h}{M}_4\\ *& -H& 0\\ *& *& -3H\end{array}\right]\left({\delta }^{\perp }\right)<0$, (7)

${\Gamma }_7\left(h\left(t\right)=h\right)={\left({\delta }^{\perp }\right)}^{\text{T}}\left[\begin{array}{ccc}\Xi & \sqrt{h}{M}_1& \sqrt{h}{M}_2\\ *& -H& 0\\ *& *& -3H\end{array}\right]\left({\delta }^{\perp }\right)<0$, (8)

${\Gamma }_8={\left({\delta }^{\perp }\right)}^{\text{T}}\left(-{\gamma }^2{h}^2{J}_2+{\Gamma }_6\right)\left({\delta }^{\perp }\right)<0$, ${\Gamma }_9={\left({\delta }^{\perp }\right)}^{\text{T}}\left(-{\left(1-\gamma \right)}^2{h}^2{J}_2+{\Gamma }_7\right)\left({\delta }^{\perp }\right)<0$,(9)

则时滞神经网络系统(1)是渐近稳定的。

其中

$\Xi \left(h\left(t\right)\right)={\displaystyle \underset{n=1}{\overset{8}{\sum }}{\Pi }_n}$, ${\Pi }_1=\text{sym}\left\{G_1^{\text{T}}P{G}_2\right\}$, ${\Pi }_3=h^2{G}_9^{\text{T}}R{G}_9-G_{10}^{\text{T}}{\Gamma }_5{G}_{10}$,

${\Pi }_2=G_3^{\text{T}}{Q}_1{G}_3-\left(1-u\right)G_4^{\text{T}}{Q}_1{G}_4+G_3^{\text{T}}{Q}_2{G}_3-G_5^{\text{T}}{Q}_2{G}_5+\text{sym}\left\{G_7^{\text{T}}{Q}_1{G}_6+G_8^{\text{T}}{Q}_2{G}_6\right\}$,

$\begin{array}{c}{\Pi }_4=h{G}_{11}^{\text{T}}Z{G}_{11}-\frac{1}{h}{G}_{12}^{\text{T}}{\Gamma }_3{G}_{12}-\frac{1}{h}{G}_{13}^{\text{T}}{\Gamma }_4{G}_{13}+\text{sym}\left\{-e_4^{\text{T}}\left(Y_2+X_1\right)\left(e_1-e_2\right)-e_5^{\text{T}}\left(Y_2+X_2\right)\left(e_2-e_3\right)\right\}\\ -h\left(t\right)e_4^{\text{T}}{Y}_1{e}_4-\left(h-h\left(t\right)\right)e_5^{\text{T}}{Y}_1{e}_5-e_2^{\text{T}}\left(X_1-X_2\right)e_2+e_1^{\text{T}}{X}_1{e}_1-e_3^{\text{T}}{X}_2{e}_3\end{array}$,

${\Pi }_5=h{f}_{0}H{f}_0+\text{sym}\left\{G_{14}^{\text{T}}{M}_1{G}_{15}+G_{14}^{\text{T}}{M}_2{G}_{16}+G_{14}^{\text{T}}{M}_3{G}_{17}+G_{14}^{\text{T}}{M}_4{G}_{18}\right\}$,

$\begin{array}{l}{\Pi }_6=\text{sym}\left\{\left[{\left(e_{10}-L_2{W}_0{e}_1\right)}^{\text{T}}{V}_1+{\left(L_1{W}_0{e}_1-e_{10}\right)}^{\text{T}}{V}_2\right]W_0{f}_0\right\}\\ +\text{sym}\left\{\left[{\left(e_{12}-L_2{W}_0{e}_3\right)}^{\text{T}}{V}_3+{\left(L_1{W}_0{e}_3-e_{12}\right)}^{\text{T}}{V}_4\right]W_0{e}_9\right\}\end{array}$,

$\begin{array}{c}{\Pi }_7=\text{sym}\left\{{\left[e_{10}-e_{11}-L_2{W}_0\left(e_1-e_2\right)\right]}^{\text{T}}{T}_{12}\left[L_1{W}_0\left(e_1-e_2\right)-\left(e_{10}-e_{11}\right)\right]\right\}\\ +\text{sym}\left\{{\left[e_{10}-e_{12}-L_2{W}_0\left(e_1-e_3\right)\right]}^{\text{T}}{T}_{13}\left[L_1{W}_0\left(e_1-e_3\right)-\left(e_{10}-e_{12}\right)\right]\right\}\\ +\text{sym}\left\{{\left[e_{11}-e_{12}-L_2{W}_0\left(e_2-e_3\right)\right]}^{\text{T}}{T}_{23}\left[L_1{W}_0\left(e_2-e_3\right)-\left(e_{11}-e_{12}\right)\right]\right\}\\ +\text{sym}\left\{{\left(e_{10}-L_2{W}_0{e}_1\right)}^{\text{T}}{T}_1\left(L_1{W}_0{e}_1-e_{10}\right)\right\}+\text{sym}\left\{{\left(e_{11}-L_2{W}_0{e}_2\right)}^{\text{T}}{T}_2\left(L_1{W}_0{e}_2-e_{11}\right)\right\}\\ +\text{sym}\left\{{\left(e_{12}-L_2{W}_0{e}_3\right)}^{\text{T}}{T}_3\left(L_1{W}_0{e}_3-e_{12}\right)\right\}\end{array}$,

${\Pi }_8=\text{sym}\left\{{\left(e_{13}-L_2{e}_4\right)}^{\text{T}}{D}_1\left(L_1{e}_4-e_{13}\right)\right\}+\text{sym}\left\{{\left(e_{14}-L_2{e}_5\right)}^{\text{T}}{D}_2\left(L_1{e}_5-e_{14}\right)\right\}$,

$\Upsilon =h\left(t\right)G_{14}^{\text{T}}\left(\frac{3M_1{H}^{-1}{M}_1^{\text{T}}+M_2{H}^{-1}{M}_2^{\text{T}}}{3}\right)G_{14}+\left(h-h\left(t\right)\right)G_{14}^{\text{T}}\left(\frac{3M_3{H}^{-1}{M}_3^{\text{T}}+M_4{H}^{-1}{M}_4^{\text{T}}}{3}\right)G_{14}$,

$e_i=\left[\begin{array}{ccc}{0}_{n,\left(i-1\right)n}& I_n& 0_{n,\left(9-i\right)n}\end{array}\right]\left(i=1,2,\cdots ,9\right)$,

$G_1=\text{col}\left\{e_1,e_3,h\left(t\right)e_4,h\left(t\right)e_6,h\left(t\right)e_4+\left(h-h\left(t\right)\right)e_5,e_{13},e_{13}+e_{14}\right\}$, $G_4=\text{col}\left\{e_2,e_8,e_{11},e_1,e_3,h\left(t\right)e_4\right\}$,

$G_2=\text{col}\left\{f_0,e_9,e_1-\left(1-u\right)e_2,h\left(t\right)\left(e_1-\left(1-u\right)e_4\right),e_1-e_3,e_{10}-\left(1-u\right)e_{11},e_{10}-e_{12}\right\}$,

$G_3=\text{col}\left\{e_1,f_0,e_{10},e_1,e_3,e_0\right\}$, $G_5=\text{col}\left\{e_3,e_9,e_{12},e_1,e_3,h\left(t\right)e_4+\left(h-h\left(t\right)\right)e_5\right\}$,

$G_6=\text{col}\left\{e_0,e_0,e_0,f_0,e_9,e_1\right\}$, $G_7=\text{col}\left\{h\left(t\right)e_4,e_1-e_2,e_{13},h\left(t\right)e_1,h\left(t\right)e_3,h\left(t\right)e_6\right\}$,

$G_8=\text{col}\left\{h\left(t\right)e_4+\left(h-h\left(t\right)\right)e_5,e_1-e_3,e_{13}+e_{14},h{e}_1,h{e}_3,h\left(t\right)e_6+\left(h-h\left(t\right)\right)e_7+h\left(t\right)\left(h-h\left(t\right)\right)e_4\right\}$,

$G_9=\text{col}\left\{e_1,f_0,e_{10}\right\}$, $G_{10}=\text{col}\left\{h\left(t\right)e_4,e_1-e_2,e_{13},\left(h-h\left(t\right)\right)e_5,e_2-e_3,e_{14}\right\}$, $G_{11}=\text{col}\left\{e_1,f_0\right\}$,

$G_{12}=\text{col}\left\{e_1-e_2,e_2-e_3\right\}$, $G_{13}=\text{col}\left\{h\left(t\right)e_4-2e_6,2e_4-e_1-e_2,\left(h-h\left(t\right)\right)e_5-2e_7,2e_5-e_2-e_3\right\}$,

$G_{14}=\text{col}\left\{e_1,e_2,e_3,e_4,e_5,e_6,e_7,e_8,e_9,e_{10},e_{11},e_{12},e_{13},e_{14}\right\}$, $G_{15}=e_1-e_2$, $G_{16}=e_1+e_2-2e_4$,

$G_{17}=e_2-e_3$, $G_{18}=e_2+e_3-2e_5$, $G_{19}=\text{col}\left\{e_0,e_0,e_4,e_6,e_4-e_5,e_0,e_0\right\}$,

$G_{20}=\text{col}\left\{e_0,e_0,e_0,e_1-\left(1-u\right)e_4,e_0,e_0,e_0\right\}$, $G_{21}=\text{col}\left\{e_0,e_0,e_0,e_0,e_0,e_4\right\}$,

$G_{22}=\text{col}\left\{e_0,e_0,e_0,e_0,e_0,e_4-e_5\right\}$, $G_{23}=\text{col}\left\{e_4,e_0,e_0,-e_5,e_0,e_0\right\}$, $G_{24}=\text{col}\left\{e_4,e_0,-e_5,e_0\right\}$.

证明:构造如下Lyapunov泛函

$V\left(t\right)={\displaystyle \underset{d=1}{\overset{6}{\sum }}{V}_d}$,

$V_1\left(t\right)={\xi }_1^{\text{T}}\left(t\right)P{\xi }_1\left(t\right)$, $V_2\left(t\right)={\displaystyle {\int }_{t-h\left(t\right)}^t{\eta }_1^{\text{T}}\left(t,s\right)Q_1}{\eta }_1\left(t,s\right)\text{d}s+{\displaystyle {\int }_{t-h}^t{\eta }_1^{\text{T}}\left(t,s\right)Q_2}{\eta }_1\left(t,s\right)\text{d}s$,

$V_3\left(t\right)=h{\displaystyle {\int }_{t-h}^t{\displaystyle {\int }_{\theta }^t{\eta }_2^{\text{T}}\left(s\right)R{\eta }_2\left(s\right)\text{d}s\text{d}\theta }}$, $V_4\left(t\right)={\displaystyle {\int }_{t-h}^t{\displaystyle {\int }_{\theta }^t{\eta }_3^{\text{T}}\left(s\right)Z{\eta }_3\left(s\right)\text{d}s\text{d}\theta }}$,

$V_5\left(t\right)={\displaystyle {\int }_{t-h}^t{\displaystyle {\int }_{\theta }^t{\stackrel{\dot{}}{x}}^{\text{T}}\left(s\right)H\stackrel{\dot{}}{x}\left(s\right)\text{d}s\text{d}\theta }}$,

$V_6\left(t\right)=2{\displaystyle \underset{i=1}{\overset{n}{\sum }}{\displaystyle {\int }_0^{W_{0i}x\left(t\right)}\left[V_{1i}{g}_{i1}\left(s\right)+V_{2i}{g}_{i2}\left(s\right)\right]\text{d}s}}+2{\displaystyle \underset{i=1}{\overset{n}{\sum }}{\displaystyle {\int }_0^{W_{0i}x\left(t-h\right)}\left[V_{3i}{g}_{i1}\left(s\right)+V_{4i}{g}_{i2}\left(s\right)\right]\text{d}s}}$.

对 $V\left(t\right)$ 求导，可得

${\stackrel{\dot{}}{V}}_1\left(t\right)=2{\xi }_1^{\text{T}}\left(t\right)P{\stackrel{\dot{}}{\xi }}_1\left(t\right)$, ${\stackrel{\dot{}}{V}}_3\left(t\right)=h^2{\eta }_2^{\text{T}}\left(t\right)R{\eta }_2\left(t\right)-{\displaystyle {\int }_{t-h}^t{\eta }_2^{\text{T}}\left(s\right)R{\eta }_2\left(s\right)\text{d}s}$,