为减小超调量,采用了微分反馈。
论述了伪微分反馈次变量(PDFSV)控制方法。
Pseudo differential feedback sub variable (PDFSV) control method is expounded.
提出了智能积分伪微分反馈控制算法在该控制系统上的应用。
An application of the Intelligent Integration PDF algorithm is proposed in this control system.
考虑了基于输出及其微分反馈的广义二阶动力学系统输出渐近跟踪设计。
Design of output asymptotic tracking for a class of descriptor second-order dynamical systems based on output plus derivative feedback is considered.
主电源采用GTO直流斩波器。主控采用带微分反馈环节的开关斩控模式。
GTO dc chopper is adopted for the main power supply while the switch mode control with derivative feedback loop is adopted for the main controller.
在已有的几种混沌信号的控制方法基础上,提出了用状态变量的一阶微分反馈法。
Based on existed methods of chaotic control, a method of controlling chaos is proposed, in which only a single variable differential feedback is used.
基于一类矩阵方程的参数化解,给出了该比例加微分反馈特征结构配置设计参数化方法。
Based on parametric solutions for a type of matrix equations, a parametric method for this eigen-structure disposition problem is propose.
采用伪微分反馈控制(PDF)策略对永磁电磁轴承进行控制,建立PD F控制模型。
A control strategy name PDF control is used in permanent magnet electromagnetism bearing. Then the model of PDF control system is founded.
在此基础上提出了利用输出电压的脉冲微分反馈对这类电路系统中的混沌进行控制的方法。
Then based on the above analysis, we present the method of using output voltage pulse differential feedback to control chaos in the buck converter.
利用自适应高阶微分反馈控制器实现倒立摆的鲁棒镇定与调节,实现了SISO和MIMO混沌系统控制与同步。
We applied successfully the proposed adaptive HODFC to the inverted pendulum stabilization and regulation, and the SISO and MIMO chaotic system control synchronization.
另外,基于所提出的估计器,本文设计了不依赖非线性系统模型的高阶微分反馈控制器。该控制器稳定性好,鲁棒性强。
Further more, based on the estimator a high order differential feedback controller is designed, which does not rely on the model of the nonlinear system, and has well stability and robustness.
把非线性系统的微分几何理论与混沌系统的同步控制目标相结合,设计了蔡氏电路混沌系统的标量混沌信号同步控制的非线性反馈控制器。
Combining the nonlinear control system theory and the aim of chaos synchronization, we designed a nonlinear feedback controller for synchronizing the scalar output signal of Chua's Circuits system.
全状态反馈控制所引入的微分控制,可以预见系统响应趋势,它的引入可以有效地抑制速度响应超调。
Differential control introduced by all state feedback control could forecast the trend of system response, and effectively restrain speed overshoot.
进一步应用基于微分几何的反馈线性化方法,将原非线性系统等价为完全可控型线性化模型。
By means of the feedback linearization procedure of differential geometry, an equivalent, fully controllable and linear model was derived via a homomorphic transformation for the AMT clutch system.
基于微分方程不变性原理,我们提出了一个简单、系统、严格的自适应反馈控制器来非线性地稳定任何混沌系统。
Based on the invariance principle of differential equations a simple, systematic and rigorous adaptive-feedback controller is proposed to stabilize nonlinearly any chaotic systems.
提出了“局部激励应变补偿”和把通常的微分负反馈改为低截止频率的惯性环节正反馈的控制新方案。
A new control approach is presented with a "local strain compensation" and a low cutoff frequency inertial link feedback in place of the differential one.
主要介绍了变结构控制、反馈线性化的微分几何方法、逆系统方法、直接反馈线性化等方法的基本思想和基本问题。
The idea and basic problem in variable structure control, differential geometry method on feedback linearization , inverse system method, direct feedback linearization method are mainly described.
对非线性控制系统的直接反馈线性化(DFL)方法与微分几何反馈线性化方法进行了比较研究。
Comparison between the direct feedback Iinearization (DFL) theory and the differential geometric feedback linearization theory for nonlinear control systems is presented.
微分代数采用动态反馈控制实现一类非线性系统的控制,平滑性是微分代数的重要概念。
Differential algebraic strategy can be applied to address the dynamic feedback control problems effectively in the nonlinear systems, with Flatness an important concept in the differential algebra.
自抗绕控制器由三部分组成:跟踪微分器、扩张状态观测器和非线性状态误差反馈控制律。
The auto-disturbance rejection controller is composed of three parts: tracking-differentiator, extended state observer and nonlinear state error feedback control law.
根据极地轨道地磁场变化的特性,利用卫星的姿态角和姿态角速率作为反馈信号,提出了一种采用磁力矩器的比例微分(PD)控制规律设计方法。
Taking into account properties of the geomagnetic field, a new PD magnetic control law using the feedback information of attitude Angle and attitude rate is developed.
采用高频脉宽调制功率驱动电路进行电磁阀的高速强力驱动,并利用电流微分信号有效反馈了控制阀关闭始点。
The ECU accomplishes the fast energizing of the solenoid valve by driving circuit with high frequency PWM, and detects the start of injection by the differential signal of driving current.
运用微分几何方法讨论了存在相对阶的一般非线性控制系统的局部反馈渐近镇定问题。
Local feedback asymptotic stabilization problems for the general nonlinear systems which exist a relative degree are discussed.
考虑连续广义系统的圆形区域极点配置问题,采用微分状态反馈的方法设计控制律使得闭环系统正则,无脉冲且闭环极点位于给定的圆形区域内。
The objective was to design derivative state feedback controllers so that the closed-loop system was regular, impulse-free, and the closed-loop poles was to be placed in a given region.
目前大多数反馈控制系统的控制器采用比例、积分、微分控制算法(PID)。
Most current feedback systems seem to have been designed around the proportion. Integral and derivative type of control algorithm (PID).
其中的反馈参数是通过求解非线性微分方程组的两点边值问题而得到的。
The feedback parameters are obtained by solving a nonlinear, two-point boundary-value problem.
阐述了温室控制中常用的方法,如分步控制、整体控制、反馈控制、比例控制、积分控制、微分控制、前馈控制的特点。
The common control methods, such as step control, integrate control, feed back, proportional, integral, derivative and feed forward, were described.
对异步电动机的矢量控制和基于微分几何理论的非线性多输入多输出状态反馈两种解耦控制方案作理论和试验比较研究。
A comparative study of two decoupling control methods based on vector control and nonlinear multi-input-multi-output state-feedback based on theory of differential geometry is researched.
对异步电动机的矢量控制和基于微分几何理论的非线性多输入多输出状态反馈两种解耦控制方案作理论和试验比较研究。
A comparative study of two decoupling control methods based on vector control and nonlinear multi-input-multi-output state-feedback based on theory of differential geometry is researched.
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