Fault-tolerant motion planning for a hexapod robot with single-leg failure using a foot force control method

IF 2.3 4区 计算机科学 Q2 Computer Science International Journal of Advanced Robotic Systems Pub Date : 2022-09-01 DOI:10.1177/17298806221121070
B. You, Yaojin Fan, Dawei Liu
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Abstract

Hexapod robots are widely used for resource exploration, post-disaster rescue, and military equipment. They typically travel on rugged and complex roads. The robot itself has a high probability of failure owing to mechanical failure, driving motor failure, or external environmental interference. To improve the adaptability of the robot to a complex environment, a motion control method for fault-tolerant gait was designed. The trajectory generator based on zero-moment point information can generate a smooth desired trajectory for the body’s center of mass, thereby improving the robot’s zero-moment point trajectory tracking effect and motion stability. The force-distribution algorithm based on torque optimization selects the minimum square sum of the driving force as the objective function and reduces the number of constraint equations through QR decomposition to increase the speed at which the expected contact force at the foot is calculated. A CoppeliaSim and MATLAB/Gurobi joint simulation platform were built to simulate and verify the fault-tolerant motion planning of the hexapod robot and foot contact force control algorithm. The feasibility and effectiveness of the fault-tolerant motion planning and foot force control algorithm applied to a hexapod robot with a single-foot failure are verified.
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基于足力控制的单腿故障六足机器人容错运动规划
六足机器人广泛用于资源勘探、灾后救援和军事装备。他们通常在崎岖复杂的道路上行驶。机器人本身由于机械故障、驱动电机故障或外部环境干扰而发生故障的概率很高。为了提高机器人对复杂环境的适应性,设计了一种容错步态的运动控制方法。基于零矩点信息的轨迹生成器可以为身体质心生成平滑的期望轨迹,从而提高机器人的零矩点轨迹跟踪效果和运动稳定性。基于扭矩优化的力分配算法选择驱动力的最小平方和作为目标函数,并通过QR分解减少约束方程的数量,以提高计算脚部预期接触力的速度。建立了CoppeliaSim和MATLAB/Gurobi联合仿真平台,对六足机器人的容错运动规划和足接触力控制算法进行了仿真验证。验证了容错运动规划和足力控制算法应用于单足故障六足机器人的可行性和有效性。
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来源期刊
CiteScore
6.50
自引率
0.00%
发文量
65
审稿时长
6 months
期刊介绍: International Journal of Advanced Robotic Systems (IJARS) is a JCR ranked, peer-reviewed open access journal covering the full spectrum of robotics research. The journal is addressed to both practicing professionals and researchers in the field of robotics and its specialty areas. IJARS features fourteen topic areas each headed by a Topic Editor-in-Chief, integrating all aspects of research in robotics under the journal''s domain.
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