Concept and Strategies: Equivalent Predictive Control and Handle Point Control for Bipedal-Vehicle Transformable Robots Under Various Disturbances

IF 6.4 2区计算机科学 Q1 AUTOMATION & CONTROL SYSTEMS

IEEE Transactions on Automation Science and Engineering Pub Date : 2025-03-18 DOI:10.1109/TASE.2025.3552429

Chencheng Dong;Zhangguo Yu;Xuechao Chen;Junhang Lai;Jiayi Liu;Chao Li;Qiang Huang

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引用次数: 0

Abstract

Bipedal-vehicle transformable robots (BVTRs), equipped with driving wheels, combine the flexibility of bipedal locomotion with the speed of wheeled movement. However, maintaining balance across different formations under various external disturbances remains a significant challenge due to uncertain disturbance types and dynamic shifts between formations. To address these challenges, this paper introduces the concept of Equivalent Predictive Control (EPC), which models all disturbances as unified virtual wrenches and integrates them directly into the robot’s predictive control model, treated as an inertia-varying single rigid body. By anticipating the future impact of disturbances, EPC enhances stability and enables simultaneous handling of various disturbances. To address the challenge of dynamic changes, contact variations, and shifting constraints during formation transitions, we propose Handle Point Control (HPC). HPC simplifies multi-task tracking by reducing joint space control to a set of virtual target points, called ‘handle points’, such as knees, hips, and shoulders. This method facilitates real-time formation switching by tracking different handle points. Experiments on the BVTR platform BHR8-2 validate the effectiveness of the proposed control strategies. Note to Practitioners—This paper addresses two critical challenges for applying BVTRs in real-world industrial scenarios: 1) managing various external disturbances, and 2) overcoming the complexities associated with changing dynamics and contact situations during formation transitions. The proposed EPC strategy unifies all disturbance types and integrates them into the robot’s dynamic model, enhancing stability and adaptability across formations. The HPC method simplifies control by focusing on tracking key handle points, allowing smooth, real-time formation transitions without needing multiple optimization schemes. These methods can also be applied to other robotic systems that face similar control challenges.

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概念与策略：各种干扰下双足-车辆可变形机器人的等效预测控制和手柄点控制

双足车辆变形机器人（bvtr）是一种将双足运动的灵活性与轮式运动的速度相结合的机器人。然而，由于不确定的扰动类型和地层之间的动态变化，在各种外部扰动下保持不同地层之间的平衡仍然是一个重大挑战。为了解决这些挑战，本文引入了等效预测控制（EPC）的概念，该概念将所有干扰建模为统一的虚拟扳手，并将其直接集成到机器人的预测控制模型中，将其视为一个变惯性的单刚体。通过预测干扰的未来影响，EPC增强了稳定性，并能够同时处理各种干扰。为了解决地层转换过程中动态变化、接触变化和移动约束的挑战，我们提出了处理点控制（HPC）。HPC通过将关节空间控制减少到一组虚拟目标点（称为“手柄点”，如膝盖、臀部和肩膀）来简化多任务跟踪。该方法通过跟踪不同的处理点，实现了实时的地层切换。在BHR8-2平台上的实验验证了所提控制策略的有效性。从业人员注意事项-本文解决了在现实工业场景中应用bvts的两个关键挑战：1)管理各种外部干扰，2)克服与地层转换过程中不断变化的动态和接触情况相关的复杂性。所提出的EPC策略统一了所有干扰类型，并将其集成到机器人的动态模型中，提高了机器人的稳定性和跨编队的适应性。HPC方法通过专注于跟踪关键处理点来简化控制，无需多个优化方案即可实现平滑、实时的地层过渡。这些方法也可以应用于其他面临类似控制挑战的机器人系统。

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

IEEE Transactions on Automation Science and Engineering 工程技术-自动化与控制系统

CiteScore

12.50

自引率

14.30%

发文量

404

审稿时长

3.0 months

期刊介绍： The IEEE Transactions on Automation Science and Engineering (T-ASE) publishes fundamental papers on Automation, emphasizing scientific results that advance efficiency, quality, productivity, and reliability. T-ASE encourages interdisciplinary approaches from computer science, control systems, electrical engineering, mathematics, mechanical engineering, operations research, and other fields. T-ASE welcomes results relevant to industries such as agriculture, biotechnology, healthcare, home automation, maintenance, manufacturing, pharmaceuticals, retail, security, service, supply chains, and transportation. T-ASE addresses a research community willing to integrate knowledge across disciplines and industries. For this purpose, each paper includes a Note to Practitioners that summarizes how its results can be applied or how they might be extended to apply in practice.