Development of a Hand-Fan-Shaped Arm and a Model Predictive Controller for Leg Crossing, Walking, and One-Legged Balancing of a Wheeled-Bipedal Jumping Robot

Machines Pub Date : 2024-04-24 DOI:10.3390/machines12050284
Seho Kim, Kiwon Yeom
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Abstract

Bipedal walking robots are advancing research by performing challenging human-like movements in complex environments. Particularly, wheeled-bipedal robots are used in many indoor environments by overcoming the speed and maneuverability limitations of bipedal walking robots without wheels. However, when both wheels lose contact with the ground, maintaining lateral balance becomes challenging, and there is an increased risk of toppling over. Furthermore, utilizing robotic arms similar to human arms, in addition to wheel-based balance, could enable more precise and stable control. In this paper, we develop a wheeled-bipedal robot that is able to jump and drive while also being able to cross its legs and balance on one leg (the OLEBOT). The OLEBOT is designed with a hand-fan-shaped end-effector capable of generating compensatory torque. By tilting the hand-fan-shaped end-effector in the opposite direction, OLEBOT achieves pitch control and single-leg balance. In jumping scenario, it imitates the arm movements of a person performing stationary high jumps, while utilizing a cam-based leg joint system to boost jump height. In addition, this paper develops a control architecture based on model predictive control (MPC) to ensure stable posture in driving, jumping, and one-legged balancing scenarios for OLEBOT. Finally, the experimental results demonstrate that OLEBOT is capable of maintaining a stable posture using a wheeled-bipedal system and achieving balance in a one-legged stance.
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为轮式双足跳跃机器人的跨腿、行走和单腿平衡开发手扇形手臂和模型预测控制器
双足行走机器人能在复杂环境中做出类似人类的高难度动作,从而推动了研究的发展。特别是,有轮双足机器人克服了无轮双足行走机器人在速度和机动性方面的限制,被广泛应用于室内环境。然而,当两个轮子都失去与地面的接触时,保持横向平衡就变得非常困难,翻倒的风险也会增加。此外,除了基于轮子的平衡之外,利用类似于人类手臂的机械臂可以实现更精确、更稳定的控制。在本文中,我们开发了一种轮式双足机器人(OLEBOT),它既能跳跃和驱动,又能交叉双腿并用单腿保持平衡。OLEBOT 设计有一个能够产生补偿扭矩的手扇形末端执行器。通过向相反方向倾斜手扇形末端执行器,OLEBOT 可实现俯仰控制和单腿平衡。在跳跃场景中,它可以模仿静态跳高者的手臂动作,同时利用基于凸轮的腿部关节系统来提高跳跃高度。此外,本文还开发了一种基于模型预测控制(MPC)的控制架构,以确保 OLEBOT 在驾驶、跳跃和单腿平衡场景中的稳定姿态。最后,实验结果表明,OLEBOT 能够使用轮式双足系统保持稳定姿态,并在单足站立时实现平衡。
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