基于支持向量机的一类混沌系统自适应逆控制

本文研究了基于支持向量机回归自适应逆控制的混沌控制方法,用支持向量机建立系统的辨识器,同时在控制过程可逆的条件下设计基于支持向量回归的系统逆控制器.将该自适应逆控制的方法应用于Lorenz混沌系统的控制,仿真结果表明在系统带有不确定性和测量噪声的情况下,该方法可以有效的将混沌系统的状态控制到给定状态.     

感应电机矢量控制系统的SVM—FIS自学习控制

研究交流电机系统特性,针对常规模糊推理系统自学习能力不强,用支持向量机与模糊系统结合,提出了一种支持向量机-模糊推理系统,由支持向量机实现模糊推理系统的自学习.设计一种基于自适应混沌优化算法的支持向量机-模糊推理自学习控制器,并将其应用于无速度传感器感应电机矢量控制系统的速度控制.控制系统采用定转子自适应磁通观测器估计磁通,用转速动态估计器来估算转子转速.仿真结果表明,控制方法响应速度快,鲁棒性强,稳定性好,是一种有效的控制方法.     

基于小波支持向量机的木材干燥控制技术研究

针对木材干燥系统强耦合非线性的特性,提出了一种基于小波最小二乘支持向量机的预测控制方法.讨论了利用小波支持向量机对木材干燥系统进行系统识别的方法,并将辨识模型应用于预测控制算法,实现了木材干燥的自适应控制.仿真结果表明,基于小波支持向量机的预测控制技术具有较好的鲁棒性,对木材干燥系统有很好的实用性.     

一类非线性系统基于最小二乘支持向量机的直接自适应控制

提出一类非线性系统基于最小二乘支持向量机的直接自适应控制方法.该方法采用最小二乘支持向量机构造自适应控制器,自适应控制器参数的在线调整规律由Lyapunov稳定性理论导出,并严格证明了闭环系统的渐近稳定性.仿真研究表明了此控制方案的可行性和有效性.     

支持向量机在PID控制器参数整定中的仿真研究

PID控制是应用最为广泛的控制方法,由于系统中存在非线性和时变性,影响建立精确的模型,系统性能.为了解决控制参数整定,改善系统性能,提出一种基于支持向量机的PID控制器参数整定方法.通过将支持向量机和PID控制器相结合建立支持向量机的参数整定模型,在控制过程中将PID控制的参数作为支持向量机的输入,构造参数自适应学习的PID控制器,在控制过程中动态调整PID的三个控制参数,进行仿真的在线整定.仿真结果表明,支持向量机的PID控制方法在处理非线性和时变系统时,提高了实时性能,增强系统稳定性,并获得更好的控制效果,为通用非线性PID控制器设计提供了依据.     

基于最小二乘支持向量机的一类非自治系统自适应控制

提出了一种基于最小二乘支持向量机(LS-SVM)的一类不确定非自治系统自适应控制器设计方法.该方法基于最小二乘支持向量机来估计对象的部分未知非线性项,并给出了最小二乘支持向量机权向量和偏移值的在线学习规则.利用李亚普诺夫理论严格证明了整个闭环系统的跟踪误差、控制器参数以及最小二乘支持向量机权参数和偏移值的一致最终有界.此控制方法可以保证对象在线稳定地跟踪任何光滑的目标轨迹,仿真结果表明了此控制方法的可行性和有效性.     

基于最小二乘支持向量机的非线性系统鲁棒自适应跟踪控制

提出了一种基于最小二乘支持向量机的非线性系统鲁棒自适应跟踪控制方法. 该方法通过最小二乘支 持向量机在线修正由于建模误差、不确定因素等引起的非线性系统逆误差,使得系统输出可以准确跟踪参考模型输 出. 最小二乘支持向量机的参数调整规律由李亚普诺夫稳定性理论导出. 文中证明了非线性系统的稳定性,仿真结果 证明了该方法的有效性.     

基于最小二乘支持向量机的预测控制

最小二乘支持向量机（LS—SVM）方法克服了经典二次规划方法求解支持向量机的维数灾问题。适合于大样本的学习。提出一种新的基于LS—SVM模型的预测控制结构,对一典型非线性系统-连续搅拌槽反应器（CSTR）的仿真表明,该控制方案表现出优良的控制品质并能适应被控对象参数的变化,具有较强的鲁棒性和自适应能力。     

基于支持向量机的非线性预测控制技术

探讨了利用支持向量机进行非线性系统辨识的方法,并将支持向量机模型应用到非线性预测控制,提出了基于支持向量机模型的非线性预测控制算法.对一个CSTR反应器的仿真表明,支持向量机在小样本情况下具有良好的非线性建模能力和泛化能力.基于支持向量机的预测控制具有很好的控制性能,为通用非线性控制提供了一种新的控制思路.􀁽     

基于支持向量机的激光焊接过程辨识与控制

激光焊接过程数学模型足一个较强非线性的数学模型,通常的线性辨识方法无法得到它精确的数学模型.支持向量机作为一种新的机器学习方法,具有较强的非线性拟合能力,应用支持向量机非线性系统回归建模方法,辨识出具有典型非线性特性的焊接过程模型,并采用预测控制算法对焊接过程进行控制.实验证明,支持向量机对非线性系统具有很好的拟合效果,基于支持向量机的预测控制具有较好的非线性控制效果.     

Nonlinear robust adaptive Cartesian impedance control of UAVs equipped with a robot manipulator

In this paper, a new nonlinear robust adaptive impedance controller is addressed for Unmanned Aerial Vehicles (UAVs) equipped with a robot manipulator that physically interacts with environment. A UAV equipped with a robot manipulator is a novel system that can perform different tasks instead of human being in dangerous and/or inaccessible environments. The objective of the proposed robust adaptive controller is control of the UAV and its robotic manipulator’s end-effector impedance in Cartesian space in order to have a stable physical interaction with environment. The proposed controller is robust against parametric uncertainties in the nonlinear dynamics model of the UAV and the robot manipulator. Moreover, the controller has robustness against the bounded force sensor inaccuracies and bounded unstructured modeling (nonparametric) uncertainties and/or disturbances in the system. Tracking performance and stability of the system are proved via Lyapunov stability theorem. Using simulations on a quadrotor UAV equipped with a three-DOF robot manipulator, the effectiveness of the proposed robust adaptive impedance controller is investigated in the presence of the force sensor error, and parametric and non-parametric uncertainties.     

Projection operator-based robust adaptive control of an aerial robot with a manipulator

This paper describes a quadcopter manipulator system, an aerial robot with an extended workspace, its controller design, and experimental validation. The aerial robot is based on a quadcopter with a three degree of freedom robotic arm connected to the base of the vehicle. The work aims to create a stable airborne robot with a robotic arm that can work above and below the airframe, regardless of where the arm is attached. Integrating a robotic arm into an underactuated, unstable system like a quadcopter can enhance the vehicle's functionality while increasing instability. To execute a mission with accuracy and reliability during a real-time task, the system must overcome the inter-coupling effects and external disturbances. This work presents a novel design for a robust adaptive feedback linearization controller with a model reference adaptive controller and hardware implementation of the quadcopter manipulator system with plant uncertainties. The closed-loop stability of the aerial robot and the tracking error convergence with the robust controller is analyzed using Lyapunov stability analysis. The quadcopter manipulator system is custom developed in the lab with an off-the-shelf quadcopter and a 3D-printed robotic arm. The robotic system architecture is implemented using a Jetson Nano companion computer for autonomous onboard flight. Experiments were conducted on quadcopter manipulator system to evaluate the autonomous aerial robot's stability and trajectory tracking with the proposed controller.     

作业型飞行机器人动态滑翔抓取的鲁棒自适应控制

作业型飞行机器人是指将多自由度机械臂固连在飞行机器人上的一类新型机器人系统,它能够对周围环境施加主动影响,同时也存在较为复杂的动力学性能.本文针对作业型飞行机器人滑翔抓取物体时所受到的摩擦力和接触力问题以及在飞行过程中产生的转动惯量变化问题,设计了一种整体式鲁棒自适应控制策略.首先在作业型飞行机器人系统动力学建模中引入摩擦力和接触力模型,考虑飞行机器人转动惯量为有界变量,提高了建模和抓取的精度.然后,为减弱滑翔抓取产生的剧烈扰动对飞行控制性能的影响,设计了一种抗扰动的鲁棒自适应控制器,并使用区间矩阵法对转动变量变化进行补偿控制.接着,通过Lyapunov稳定性理论证明了系统的稳定性.最后通过仿真对比实验,验证了所提出方法的有效性和优势.     

Robust Adaptive Dead Zone Technology for Fault-Tolerant Control of Robot Manipulators Using Neural Networks

In this paper, a multi-layered feed-forward neural network is trained on-line by robust adaptive dead zone scheme to identify simulated faults occurring in the robot system and reconfigure the control law to prevent the tracking performance from deteriorating in the presence of system uncertainty. Consider the fact that system uncertainty can not be known a priori, the proposed robust adaptive dead zone scheme can estimate the upper bound of system uncertainty on line to ensure convergence of the training algorithm, in turn the stability of the control system. A discrete-time robust weight-tuning algorithm using the adaptive dead zone scheme is presented with a complete convergence proof. The effectiveness of the proposed methodology has been shown by simulations for a two-link robot manipulator.     

State and Impedance Reflection Based Control Interface for Bilateral Telerobotic System with Asymmetric Delay

In this paper, we investigate state and imped-ance reflection based robust control strategy for bilateral shared telerobotic system under unsymmetrical time varying delay. Shared input for both master and slave robot is designed by combining delayed position and position-velocity signals with impedance reflection properties of the interaction between slave and environment and between human and master robot manipulator. Adaptive control algorithm is proposed to estimate the interaction properties between human and master manipulator and between slave and remote environment. Then, the delayed estimated interaction properties are reflected back to the master and slave robot manipulator to match with the estimated impedance properties of the interaction between human and remote environment. We combine robust term with adaptive control term to deal with the uncertainty associated with gravity loading vector, unmodeled dynamic and external disturbance. The stability conditions with time varying delays are derived by using Lyapunov-Krasovskii functional. Experimental results are given to demonstrate the validity of the proposed design for real-time applications.     

一类关于不确定性机器人的鲁棒控制策略1)

基于计算力矩结构,研究参数和结构不确定的机器人轨迹跟踪的鲁棒控制策略.其特点是利用了机器人不确定动力学的集中包络函数,在该包络函数已知的情况下,设计的非线性连续补偿控制律能够有效消除系统的不确定性影响,保证系统达到三种不同的稳定性结果.另外,在该包络函数参数未知时,还设计了一个新颖的在线辨识器,可保证系统指数意义下的渐近收敛或一致有界.     

一类关于不确定性机器人的鲁棒控制策略

基于计算力矩结构,研究参数和结构不确定的机器人轨迹跟踪的鲁棒控制策略.其 特点是利用了机器人不确定动力学的集中包络函数,在该包络函数已知的情况下,设计的非 线性连续补偿控制律能够有效消除系统的不确定性影响,保证系统达到三种不同的稳定性结 果.另外,在该包络函数参数未知时,还没计了一个新颖的在线辨识器,可保证系统指数意义 下的渐近收敛或一致有界.     

A robust fuzzy logic controller for robot manipulators withuncertainties

Owing to load variation and unmodeled dynamics, a robot manipulator can be classified as a nonlinear dynamic system with structured and unstructured uncertainties. In this paper, the stability and robustness of a class of the fuzzy logic control (FLC) is investigated and a robust FLC is proposed for a robot manipulator with uncertainties. In order to show the performance of the proposed control algorithm, computer simulations are carried out on a simple two-link robot manipulator.     

Observer-based adaptive control of robot manipulators: Fuzzy systems approach

This paper presents a fuzzy adaptive control suitable for motion control of multi-link robot manipulators with structured and unstructured uncertainties. When joint velocities are available, full state fuzzy adaptive feedback control is designed to ensure the stability of the closed loop dynamic. If the joint velocities are not measurable, an observer is introduced and an adaptive output feedback control is designed based on the estimated velocities. In the proposed control scheme, we need not derive the linear formulation of robot dynamic equation and tune the parameters. To reduce the number of fuzzy rules of the fuzzy controller, we consider the properties of robot dynamics and the decomposition of the uncertainties terms. The proposed controller is robust against uncertainties and external disturbance. Further, it is shown that required stability conditions, in both cases, can be formulated as LMI problems and solved using dedicated software. The validity of the control scheme is demonstrated by computer simulations on a two-link robot manipulator.     

Robust adaptive control of an underactuated free-flying space robot under a non-holonomic structure in joint space

This paper introduces a robust adaptive control scheme for an underactuated free-flying space robot under non-holonomic constraints. An underactuated robot manipulator is defined as a robot that has fewer joint actuators than the number of total joints. Because, if one of the joints is out of order, it is so hard to repair the joint, especially in space, the control of such a robot manipulator is important. However, it is difficult to control an underactuated robot manipulator because of the reduced dimension of the input space, i.e. the non-holonomic structure of the underactuated system. The proposed scheme does not need to assume that the exact dynamic parameters must be known. It is analysed in joint space to control the underactuated robot mounted on the space station under parametric uncertainties and external disturbances. The simulation results have shown that the proposed method is very feasible and robust for a two-link planar free-flying space robot with one passive joint.