无电池设备的能量自适应实时传感

Mohsen Karimi, Yidi Wang, Hyoseung Kim
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引用次数: 3

摘要

无电池能量收集设备的使用被认为是一种很有前途的解决方案,因为它们的维护要求低,并且能够在恶劣的环境中工作。然而,这些设备必须从环境能源中收集能量,并定期执行实时传感任务,同时满足数据新鲜度的限制,这尤其具有挑战性,因为能源通常是不可靠的和间歇性的。在本文中,我们开发了一种用于无电池设备的能量自适应实时传感框架。该框架包括一个轻量级的基于机器学习的能量预测器,它能够在微控制器设备上运行,并根据能量轨迹预测能量可用性和强度。利用这一点,该框架通过有效地考虑每个任务的预测能量供应和由此产生的信息年龄来调整实时任务的时间表,以实现连续的传感操作并满足给定的数据新鲜度要求。我们讨论了各种自适应调度的设计选择,并评估了它们在无电池设备环境下的性能。实验结果表明,本文提出的自适应实时方法在能量利用率和数据新鲜度方面都优于基于静态方法和响应方法的现有方法。
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Energy-Adaptive Real-time Sensing for Batteryless Devices
The use of batteryless energy harvesting devices has been recognized as a promising solution for their low maintenance requirements and ability to work in harsh environments. However, these devices have to harvest energy from ambient energy sources and execute real-time sensing tasks periodically while satisfying data freshness constraints, which is especially challenging as the energy sources are often unreliable and intermittent. In this paper, we develop an energy-adaptive real-time sensing framework for batteryless devices. This framework includes a lightweight machine learning-based energy predictor that is capable of running on microcontroller devices and predicting the energy availability and intensity based on energy traces. Using this, the framework adapts the schedule of real-time tasks by effectively taking into account the predicted energy supply and the resulting age of information of each task, in order to achieve continuous sensing operations and satisfy given data freshness requirements. We discuss various design choices for adaptive scheduling and evaluate their performance in the context of batteryless devices. Experimental results show that the proposed adaptive real-time approach outperforms the recent methods based on static and reactive approaches, in both energy utilization and data freshness.
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来源期刊
CiteScore
1.70
自引率
14.30%
发文量
17
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