Gait planning based on bionic quadruped robot

IF 1.5 Q2 ENGINEERING, MULTIDISCIPLINARY

Engineering Research Express Pub Date : 2024-09-06 DOI:10.1088/2631-8695/ad7442

Zhao Liu, Zhe Huang, Yuanhui Cui

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引用次数: 0

Abstract

Based on the ankylosaurus, a four-legged robot structure with 14 degrees of freedom was designed in this study. The kinematic model was established using the Denavit-Hartenberg (D-H) method. The inverse kinematics of the robot was analyzed, and the angle equations of each leg joint were obtained. In order to reduce the kinetic energy generated when leaving the ground and landing, the compound cycloid was modified. The modified foot curve effectively reduces energy and meets the kinematic requirements. On the basis of the foot trajectory, the diagonal leg phase difference was set to 0.5, and the diagonal gait was adopted as the gait of the bionic quadrupled robot. Simulink software was used to construct the simulation environment, and the maximum error of the simulation results and the theoretical step height was 2.05%, and the step length maximum error was 2.39%. During walking, the thigh joint angle was −92.82° to −80.21°, and the hip joint angle was 22.23° to 43.83°. Compared with the simulation trajectory and the theoretical curve, because the experiment did not consider the balance of the fuselage, there was a certain error when the leg was raised to the highest point. Overall, the gait planning strategy designed in this study basically achieves the expected effect, lays a certain foundation for the practical application of the bionic quadruped dinosaur robot, and also provides a reference for the subsequent research.

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基于仿生四足机器人的步态规划

本研究以踝龙为基础，设计了一种具有 14 个自由度的四足机器人结构。采用 Denavit-Hartenberg (D-H) 方法建立了运动学模型。对机器人的逆运动学进行了分析，并得到了各腿部关节的角度方程。为了减少离地和着地时产生的动能，对复合摆线进行了修改。修改后的脚部曲线有效降低了能量，满足了运动学要求。在脚部轨迹的基础上，将对角线腿相位差设为 0.5，并采用对角线步态作为仿生四足机器人的步态。使用 Simulink 软件构建仿真环境，仿真结果与理论步高的最大误差为 2.05%，步长的最大误差为 2.39%。行走过程中，大腿关节角度为-92.82°至-80.21°，髋关节角度为22.23°至43.83°。与模拟轨迹和理论曲线相比，由于实验没有考虑机身的平衡问题，当腿抬到最高点时存在一定误差。总的来说，本研究设计的步态规划策略基本达到了预期效果，为仿生四足恐龙机器人的实际应用奠定了一定的基础，也为后续研究提供了参考。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Engineering Research Express Engineering-Engineering (all)

CiteScore

2.20

自引率

5.90%

发文量

192