仿人机器人
控制器(灌溉)
控制理论(社会学)
反推
计算机科学
控制工程
非线性系统
运动学
机器人
工程类
人工智能
自适应控制
控制(管理)
农学
物理
生物
经典力学
量子力学
作者
Juan Manuel Gomez-Quispe,Gustavo Pérez-Zúñiga,Diego Arce,Fiorella Urbina,Sareli Gibaja,Renato Paredes,Francisco Cuéllar
出处
期刊:Sensors
[Multidisciplinary Digital Publishing Institute]
日期:2023-01-03
卷期号:23 (1): 552-552
被引量:5
摘要
In social robotics, especially with regard to direct interactions between robots and humans, the robotic movements of the body, arms and head must make an adequate displacement to guarantee an adequate interaction, both from a functional and social point of view. To achieve this, the use of closed-loop control techniques that consider the complex nonlinear dynamics and disturbances inherent in these systems is required. In this paper, an implementation of a nonlinear controller for the tracking of trajectories and a profile of speeds that execute the movements of the arms and head of a humanoid robot based on the mathematical model is proposed. First, the design and implementation of the arms and head are initially presented, then the mathematical model via kinematic and dynamic analysis was performed. With the above, the design of nonlinear controllers such as nonlinear proportional derivative control with gravity compensation, Backstepping control, Sliding Mode control and the application of each of them to the robotic system are presented. A comparative analysis based on a frequency analysis, the efficiency in polynomial trajectories and the implementation requirements allowed selecting the non-linear Backstepping control technique to be implemented. Then, for the implementation, a centralized control architecture is considered, which uses a central microcontroller in the external loop and an internal microcontroller (as internal loop) for each of the actuators. With the above, the selected controller was validated through experiments performed in real time on the implemented humanoid robot, demonstrating proper path tracking of established trajectories for performing body language movements.
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