机器人动力学是复杂的动力学系统,对处理物体的动态响应取决于机器人动力学模型和控制算法。
Robot dynamics is a complex dynamic system, on the dynamic response of the processing object depending on the robot dynamics model and control algorithm.
研究了非完整移动机器人动力学模型中带有参数不确定和控制受限的鲁棒轨迹跟踪控制器的设计问题。
Designing of robust trajectory tracking controller for mobile robots with parametric uncertainties in the dynamic model and with bounded input is investigated.
着重讲述了机器人系统(多机器人)动力学与控制的独特性质,以及所提出的独特控制问题,这些性质与问题是单机器人控制和一般控制问题中所没有的。
Attention is paid to the specific characteristics in the dynamics and control issues appeared in multiple robot systems, which do not appear in single robot cases.
本文提出一种新的自适应控制算法,用于补偿机器人动力学方程中的非线性项和消除关节间的耦合。
A new adaptive control algorithm is proposed in this paper to compensate nonlinear terms in the dynamic equation of robot and decouple the dynamic interaction among the joints.
实现类人型机器人动态行走,必须对机器人进行动力学建模、步态设计和稳定姿态控制算法设计。
To realize dynamic walking of the humanoid robot, robot dynamic models have to be established, the control algorithm for gait and the stability postures should be designed.
通过对关节式移动机器人越障过程运动学和动力学分析,得出控制移动机器人越障时保证动态稳定性的约束条件。
Analyzed kinematics and dynamics of the obstacle negotiations for an articulated mobile robot a restriction condition to guarantee dynamic stability when it gets over the obstacles.
针对机器人动力学模型的不确定性和负载扰动,提出了一种采用神经网络的机器人迭代学习控制方法。
Aiming at dynamic model uncertainties and load disturbances of robot manipulators, an iterative learning control scheme using neural networks is presented.
运用前面所提出的动力学建模和控制设计方法,完成了全自动树枝修剪机器人的设计。
Employing the dynamic modeling and controller design method previously addressed, an automatic tree-trimming robot has been designed.
分析拟人足球机器人的运动状态,建立起拟人足球机器人运动学和动力学模型。提出一种有效的力矩控制方法。
Analysis the movement of humanoid robot, come up with the kinematic and dynamic model and a method of force moment control.
该机器人由动力系统、机械系统和控制系统组成,其控制系统主要由PIC单片机、电动机驱动电路和传感器模块三部分组成。
The whole of this robot included dynamic system, mechanical system and control system. This control system mainly included PIC single chip, motor drive circuit, and sensor module.
该机器人由动力系统、机械系统和控制系统组成,其控制系统主要由PIC单片机、电机驱动电路和传感器模块三部分组成。
This robot consists of dynamic system, mechanical system and control system. The control system mainly includes PIC single chip, motor drive circuit and sensor module.
提出一种基于步态规划分级结构的自适应网络模糊推理系统控制策略,该方法不需要确定双足机器人运动学和动力学模型。
Proposed an adaptive network fuzzy inference system control strategy based on hierarchy structure of gait planning, which do not require detailed kinematics or dynamic biped models.
本文主要针对非完整移动机器人进行运动学和动力学建模、分析与轨迹跟踪控制器设计的研究。
Analysis, kinematic and dynamical modeling and trajectory tracking controller designing for a mobile robot are studied in this thesis.
首先,分析一类两轮移动机器人的运动学模型和动力学模型,针对其轨迹跟踪控制问题,设计滑模控制器。
Firstly, a kind of kinematics model of two-wheel driven mobile robot is analyzed. Aimed at its trajectory tracking control problem, the sliding-mode controller is designed.
本文针对关节式移动机器人在斜面上运动时稳定性和安全性的要求对其进行动力学分析,利用传感器融合技术对机器人进行局部定位,提出了它的基于模糊逻辑的控制策略。
Fuzzy logic based motion control approach was proposed, using sensor fusion for robot local location, aimed at the requirement of stability and safety for articulated mobile robot moving on slope.
本文还研究设计了清扫机器人各个部件模块的供电情况,分类供电,特别是动力电源和控制电源,尽量避免相互干扰。
The article also have made a study of the power supply for each part, classify the power supply types, especially drive power and control power, in order to avoid disturbance each other.
本产品使用地铁隧道盾构机和各类机器人,机械手的动力和控制系统的电缆,具有良好的弯曲性能。
This product is suitable for power and control system cable of underground tunnel shield construction machine and all kinds of robot, manipulator and possesses good flexural properties.
基于对主从机器人控制系统的动力学分析,研究了借助力觉临场感技术实现主从医疗机器人遥操作的控制理论和设计方法。
It focuses on the control theory and design method of master-slave medical robot system, that can implement precise teleoperation by means of force telepresence technology.
建立了机器人的运动学模型和动力学模型,并利用能控性理论对机器人的姿态能控性进行了分析,为后续的机器人的控制提供了理论基础。
The dissertation constructed the robotic dynamics and motivation, used the controllable theory to analyze the robotic position control, which is the basis for later control theory.
采用李群李代数符号描述了含主被动关节机器人的动力学分析和控制问题。
Lie groups and Lie algebras were used to study the dynamics and control of robot system with active and passive joints.
对机器人动力学和运动学关系式进行线性参数化,分别对动力学待估参数和运动学待估参数设计在线修正律,在关节空间采用自适应控制。
Kinematics and dynamics can be linearized by a set of combined parameters, the update law of the parameters is designed respectively. Adaptive control is adopted in joint space.
本文进行了机器人总体方案的设计,运动机构的设计,动力源的选取和控制系统的设计。
The overall plan of the robot including the movement mechanism, the selection of power supply and the control plan was designed and specify in this paper.
移动机器人的运动学建模是其实现路径规划和动力学控制的基础,是移动机器人研究的重要内容。
Three dimensional vision modeling is the base of virtual reality(VR) system, and movement modeling is the important component of three dimensional vision modeling.
移动机器人的运动学建模是其实现路径规划和动力学控制的基础,是移动机器人研究的重要内容。
Three dimensional vision modeling is the base of virtual reality(VR) system, and movement modeling is the important component of three dimensional vision modeling.
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