IEEE 802.15.4 TSCH网络中高速率不可预测流量的调度

2017 13th International Conference on Distributed Computing in Sensor Systems (DCOSS) Pub Date : 2017-03-10 DOI:10.1109/DCOSS.2017.20

Atis Elsts, Xenofon Fafoutis, James Pope, G. Oikonomou, R. Piechocki, I. Craddock

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引用次数: 42

摘要

即将到来的物联网(IoT)应用包括使用可穿戴传感器进行实时人体活动监控。与传统的低功耗无线节点环境传感相比，这些新应用产生了更高速率的恒定流。然而，可穿戴设备仍然是电池供电，因此仅限于低功耗无线标准，如IEEE 802.15.4或低功耗蓝牙(BLE)。我们的工作解决了在IEEE 802.15.4 TSCH网络中为转发这类动态数据建立可靠的自主调度的问题。由于这些数据源的位置、无线链路的质量和转发网络的路由拓扑的先验不可预测性，预留最坏情况所需的插槽数量是浪费的，在高期望数据的条件下，这是完全不可能的。我们提出的解决方案是一种混合方法，其中专用的TSCH单元和共享的TSCH槽在同一调度中共存。我们证明了在无线链路分集的现实假设下，在TSCH调度中添加共享时隙可以提高总体分组传输速率和系统的公平性。

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Scheduling High-Rate Unpredictable Traffic in IEEE 802.15.4 TSCH Networks

The upcoming Internet of Things (IoT) applications include real-time human activity monitoring with wearable sensors. Compared to the traditional environmental sensing with low-power wireless nodes, these new applications generate a constant stream of a much higher rate. Nevertheless, the wearable devices remain battery powered and therefore restricted to low-power wireless standards such as IEEE 802.15.4 or Bluetooth Low Energy (BLE). Our work tackles the problem of building a reliable autonomous schedule for forwarding this kind of dynamic data in IEEE 802.15.4 TSCH networks. Due to the a priori unpredictability of these data source locations, the quality of the wireless links, and the routing topology of the forwarding network, it is wasteful to reserve the number of slots required for the worst-case scenario, under conditions of high expected datarate, it is downright impossible. The solution we propose is a hybrid approach where dedicated TSCH cells and shared TSCH slots coexist in the same schedule. We show that under realistic assumptions of wireless link diversity, adding shared slots to a TSCH schedule increases the overall packet delivery rate and the fairness of the system.

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2017 13th International Conference on Distributed Computing in Sensor Systems (DCOSS)

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