This paper introduces modular multivariable dynamic matrix controller.
本文介绍阶梯式模块多变量动态矩阵控制器。
The modular multivariable dynamic matrix controller (MMDMC) exploited by author and its application is introduced.
介绍我们自己开发的模块多变量动态矩阵控制(MMDMC)软件包及其应用。
If two signal importations of controller carry to merge the importation, its exportation will expand after carry use the matrix method conjunction 256 roads.
如果两个控制器的信号输入端并联输入,其输出端用矩阵方式连接后,将扩展成256路。
Optimal controller is combined of a optimal reduced order state estimator and a optimal static output feedback gain matrix.
动态反馈控制器可表示为一个最优降维状态估值器和一个最优静态反馈增益阵。
The controller to be designed is assumed to have state feedback gain variations. Design methods are presented in terms of linear matrix inequalities (LMIs).
假定所要设计的控制器存在状态反馈增益变化,设计方法是以线性矩阵不等式组的形式给出的。
Designed state feedback controller with gain is also interval matrix.
设计的状态反馈控制器,其增益也是区间矩阵。
To enhance the performance of dynamic systems, a design method of robust output-feedback controller based on the linear matrix inequality technique was proposed.
为提高动态系统的性能,提出了一种基于线性矩阵不等式技术的鲁棒输出反馈控制器设计方法。
A new test signal method based approach to design power oscillation damping (POD) controller for TCSC is proposed, by which the bulky eigenvalue calculation of state matrix can be avoided.
提出了一种基于测试信号法的TCSC功率振荡阻尼(POD)控制器的设计方法,避免了计算量庞大的状态矩阵特征值计算。
The problem of guaranteed cost control for a class of uncertain time-delayed systems was addressed. The uncertainties existed both in the systematic matrix, and in the controller gain.
研究了一类不确定时滞系统的保性能控制问题,其不确定性不仅存在于系统矩阵,而且存在于控制器的增益中。
The problem of quadratic stability and controller design for T-S fuzzy systems is studied using the linear matrix inequality(LMI)methods.
应用LMI(线性矩阵不等式)方法,研究了T-S模糊系统二次稳定性及控制器设计问题。
The optimal feedback matrix was used to weight the input variable of fuzzy controller.
利用最优反馈矩阵来加权模糊控制器的输入变量。
Linear matrix inequalities (LMI) technique provides a new solution for multi-objective controller synthesis.
线性矩阵不等式(LMI)技术为多目标控制器的综合提供了新的解决途径。
And by using linear matrix inequalities, it gives a design method for the guaranteed cost state feedback controller, including time-delay state in the controller.
利用线性矩阵不等式,给出了有记忆状态反馈保性能控制器的设计方法,所设计的控制器中含有状态时滞。
The optimal feedback gain matrix can be obtained by solving a static output feedback controller problem.
通过求解利用降维状态观测器的静态输出反馈,可得到降阶控制的最优反馈增益阵。
At last, a decoupling dual internal model controller matrix design method is proposed for multi-variable time-delay input-output system in industrial processes.
最后,针对工业过程中常见的多变量多时滞输入输出系统,提出了一种双内模解耦控制器矩阵的设计方法。
Firstly, based on linear matrix inequalities (LMIs), a sufficient and necessary condition of circular regional controller possessing integrity for descriptor linear systems is given.
首先,用线性矩阵不等式(LMI)给出了线性广义系统圆盘区域的控制器存在的充分条件。
This method can obtain the designed result of fault-tolerant controller by using the linear matrix inequality, and avoids the iterative process of the methods in existence.
该方法利用线性矩阵不等式可方便地得到容错控制器设计结果,避免了现有方法需要重复试验的过程。
The algorithm, on the basis of the principle of interactive controller and matrix similar transform, works out the approximate real matrix of a complex matrix with the method of finding extrema.
该算法是基于交互控制器和矩阵相似变换原理,用求极值方法求出复矩阵的近似实阵。
Based on the linear matrix inequality and adaptive approach, a state feedback adaptive controller is designed, which make the closed-loop system is asymptotically stable.
利用线性矩阵不等式技术和自适应参数估计方法,设计鲁棒自适应控制器,从而保证闭环系统渐近稳定。
Numerical examples show that the negative semi-definite matrix condition of exponential stability and the controller design method are feasible.
数值算例说明指数稳定的半负定矩阵条件和控制器设计方法是可行的。
Secondly, a sufficient condition for the existence of such output feedback controller is derived by means of linear matrix inequality approach.
其次,这样的输出反馈控制器存在的充分条件推导出的线性矩阵不等式方法。
Based on 2 norm estimate of matrix, stability of T S type fuzzy controller is studied and several sufficient conditions of open loop system are proposed .
利用矩阵的谱范数估计,研究了连续T-S型模糊控制器的稳定性,给出模糊开环系统稳定的充分条件。
The matrix display of organic light emitting diode (OLED) using liquid crystal display controller and driver is introduced.
本文介绍了用液晶显示控制驱动器实现有机发光二极管(OL ED)的矩阵字符显示。
It is difficult to design the closed loop gain shaping controller when the controlled plant is not a square matrix, because it is involved in the pseudo inverse of matrix.
在被控对象为非方阵的系统中,由于求解控制器时涉及到矩阵求伪逆问题,很大程度上增加了闭环增益成形算法的难度。
On the other hand, by prefixing some elements in the output feedback gain matrix, the casual condition of the controller is automatically satisfied.
同时通过预先固定反馈增益阵中的某些元素的方法,使得控制器满足因果约束的要求。
While a fuzzy system is described by a fuzzy relational matrix corresponding to the fuzzy input, the fuzzy output and the fuzzy controller.
而模糊系统是用一个与输入、输出及控制项有关的模糊关系矩阵来描述的。
The robust controller is designed using linear Matrix Inequality (LMI) for the nominal linear flight system. And then, the uncertain nonlinear input term is compensated using the neural network.
由线性矩阵不等式(LMI)设计系统标称部分的鲁棒控制器,然后利用神经网络的输出来消除系统控制输入中的不确定部分。
The system uses dot matrix liquid crystal display . and the gain Curve is field programmable with a remote controller in the system.
系统显示采用了点阵式液晶显示器,增益曲线现场可编程,并带有遥控功能。
Then, a new sufficient condition for the stability of open-loop system is proposed based on linear matrix inequality (LMI); and a fuzzy controller is designed via non-quadratic PDC control law.
然后,基于一系列线性矩阵不等式,得到了开环系统稳定的充分条件,进而又基于非二次PD C控制律,设计出了模糊控制器。
Then, a new sufficient condition for the stability of open-loop system is proposed based on linear matrix inequality (LMI); and a fuzzy controller is designed via non-quadratic PDC control law.
然后,基于一系列线性矩阵不等式,得到了开环系统稳定的充分条件,进而又基于非二次PD C控制律,设计出了模糊控制器。
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