Scaling beyond Bandwidth Limitations: Wireless Control with Stability Guarantees under Overload

ACM Transactions on Cyber-Physical Systems (TCPS) Pub Date : 2021-04-16 DOI:10.1145/3502299

Fabian Mager, Dominik Baumann, Carsten Herrmann, Sebastian Trimpe, Marco Zimmerling

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引用次数: 6

Abstract

An important class of cyber-physical systems relies on multiple agents that jointly perform a task by coordinating their actions over a wireless network. Examples include self-driving cars in intelligent transportation and production robots in smart manufacturing. However, the scalability of existing control-over-wireless solutions is limited as they cannot resolve overload situations in which the communication demand exceeds the available bandwidth. This article presents a novel co-design of distributed control and wireless communication that overcomes this limitation by dynamically allocating the available bandwidth to agents with the greatest need to communicate. Experiments on a real cyber-physical testbed with 20 agents, each consisting of a low-power wireless embedded device and a cart-pole system, demonstrate that our solution achieves significantly better control performance under overload than the state of the art. We further prove that our co-design guarantees closed-loop stability for physical systems with stochastic linear time-invariant dynamics.

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超越带宽限制的扩展:在过载下具有稳定性保证的无线控制

一类重要的网络物理系统依赖于多个代理，这些代理通过在无线网络上协调它们的行动来共同执行任务。例如智能交通领域的自动驾驶汽车和智能制造领域的生产机器人。然而，现有的无线控制解决方案的可扩展性是有限的，因为它们不能解决通信需求超过可用带宽的过载情况。本文提出了一种新的分布式控制和无线通信的协同设计，通过动态地将可用带宽分配给最需要通信的代理来克服这一限制。在一个真实的网络物理测试平台上进行了20个代理的实验，每个代理由一个低功耗无线嵌入式设备和一个推车杆系统组成，结果表明，我们的解决方案在过载情况下的控制性能明显优于目前的技术水平。我们进一步证明了我们的协同设计保证了具有随机线性定常动力学的物理系统的闭环稳定性。

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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ACM Transactions on Cyber-Physical Systems (TCPS)

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