电动液压仿人机器人的分布式实时控制架构

Subhi Jleilaty, A. Ammounah, G. Abdulmalek, L. Nouvelière, Hang Su, S. Alfayad
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摘要

目的本文旨在为电动液压仿人机器人(HYDROïD)开发一种适应性强的控制架构,以模拟人类神经系统的功能。所开发的控制架构通过在各控制器之间分配智能,克服了传统集中式和分散式系统的局限性。设计/方法/途径所提出的解决方案是一种带有机器人操作系统(ROS)的分布式实时控制架构。联合控制器具有做出决策、支配执行器和发布状态的智能。主控制器通过使用开放式机器人控制软件中间件旁的 Preempt-RT 内核来执行实时任务,而定制的联合控制器则通过免费的实时操作系统固件来确保实时功能。系统可以是集中式的,即所有组件都连接到一个中央单元;也可以是分散式的,即当主控器没有决策能力时,分布式单元充当 I/O 与主控器之间的接口。它采用集中式硬件拓扑结构,包括主控 PC 和分布式联合控制器,而软件架构则根据任务进行调整。它以分布式方式运行,以实现精确的、与力无关的运动;以分散式方式运行,以完成需要顺应性和力控制的任务。通过这种设计,可以对低级关节控制器和高级主控制器的传感器运动环路进行检查。实验验证在 HYDROïD 上进行。结果表明,与其他人形机器人相比,更新率提高了 50%,主处理器和控制任务的延迟时间缩短了 30%。
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Distributed real-time control architecture for electrohydraulic humanoid robots
Purpose This paper aims to develop an adaptable control architecture for electrohydraulic humanoid robots (HYDROïD) that emulate the functionality of the human nervous system. The developed control architecture overcomes the limitations of classical centralized and decentralized systems by distributing intelligence across controllers. Design/methodology/approach The proposed solution is a distributed real-time control architecture with robot operating system (ROS). The joint controllers have the intelligence to make decisions, dominate their actuators and publish their state. The real-time capabilities are ensured in the master controller by using a Preempt-RT kernel beside open robot control software middleware to operate the real-time tasks and in the customized joint controllers by free real-time operating systems firmware. Systems can be either centralized, where all components are connected to a central unit or decentralized, where distributed units act as interfaces between the I/Os and the master controller when the master controller is without the ability to make decisions. Findings The proposed architecture establishes a versatile and adaptive control framework. It features a centralized hardware topology with a master PC and distributed joint controllers, while the software architecture adapts based on the task. It operates in a distributed manner for precise, force-independent motions and in a decentralized manner for tasks requiring compliance and force control. This design enables the examination of the sensorimotor loop at both low-level joint controllers and the high-level master controller. Originality/value It developed a control architecture emulating the functionality of the human nervous system. The experimental validations were performed on the HYDROïD. The results demonstrated 50% advancements in the update rate compared to other humanoids and 30% in the latency of the master processor and the control tasks.
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