阿斯特罗

IF 3.5 Q2 COMPUTER SCIENCE, INFORMATION SYSTEMS ACM Transactions on Internet of Things Pub Date : 2021-07-15 DOI:10.1145/3464942
Riccardo Petrolo, Zhambyl Shaikhanov, Yingyan Lin, E. Knightly
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引用次数: 155

摘要

我们介绍了ASTRO的设计、实现和实验评估,ASTRO是一个模块化的端到端系统,用于自主联网无人机的分布式传感任务。我们介绍了在ASTRO无人机上实现不可知论传感任务的基本系统架构特征。我们通过使用机载软件定义无线电来发现和跟踪移动无线电目标来演示ASTRO的关键原理。我们展示了如何使用简单的分布式机载机器学习方法来查找和跟踪移动目标,即使所有无人机都与地面控制失去联系。此外,我们还展示了ASTRO能够找到目标,即使它隐藏在3吨重的混凝土板下,这代表了一个高度不规则的传播环境。我们的研究结果表明,尽管没有事先的训练和嘈杂的感官测量,ASTRO无人机能够在秒的尺度上学习传播环境,并以8米的平均精度定位目标。此外,ASTRO无人机能够在一段时间内以相对恒定的误差跟踪目标,即使它以接近无人机最大速度的速度移动。
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ASTRO
We present the design, implementation, and experimental evaluation of ASTRO, a modular end-to-end system for distributed sensing missions with autonomous networked drones. We introduce the fundamental system architecture features that enable agnostic sensing missions on top of the ASTRO drones. We demonstrate the key principles of ASTRO by using on-board software-defined radios to find and track a mobile radio target. We show how simple distributed on-board machine learning methods can be used to find and track a mobile target, even if all drones lose contact with a ground control. Also, we show that ASTRO is able to find the target even if it is hiding under a three-ton concrete slab, representing a highly irregular propagation environment. Our findings reveal that, despite no prior training and noisy sensory measurements, ASTRO drones are able to learn the propagation environment in the scale of seconds and localize a target with a mean accuracy of 8 m. Moreover, ASTRO drones are able to track the target with relatively constant error over time, even as it moves at a speed close to the maximum drone speed.
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来源期刊
CiteScore
5.20
自引率
3.70%
发文量
0
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