Abstract
Low-power wireless applications require different trade-off points between latency, reliability, data rate and power consumption. Given such a set of constraints, which physical layer should I be using? We study this question in the context of 6TiSCH, a state-of-the-art recently standardized protocol stack developed for harsh industrial applications. Specifically, we augment OpenWSN, the reference 6TiSCH open-source implementation, to support one of three physical layers from the IEEE802.15.4g standard: FSK 868 MHz which offers long range, OFDM 868 MHz which offers high data rate, and O-QPSK 2.4 GHz which offers more balanced performance. We run the resulting firmware on the 42-mote OpenTestbed deployed in an office environment, once for each physical layer. Performance results show that, indeed, no physical layer outperforms the other for all metrics. This article argues for combining the physical layers, rather than choosing one, in a generalized 6TiSCH architecture in which technology-agile radio chips (of which there are now many) are driven by a protocol stack which chooses the most appropriate physical layer on a frame-by-frame basis.
Highlights
Applications for low-power wireless technology are numerous, including smart building [1,2], environmental monitoring [3], precision agriculture [4], automated meter reading [5], indoor localization [6], smart grid [7] and predictive maintenance [8].Several physical layers (PHYs) exist, each finding a different trade-off between energy consumption, datarate and range
Multiplexing—OFDM), data rate ranging from 25 kbps to 800 kbps, and two frequency bands
We show that there are significant benefits of each of the radio options: FSK 868 MHz, OFDM 868 MHz, and O-QPSK 2.4 GHz, yet they all come at a certain cost
Summary
Applications for low-power wireless technology are numerous, including smart building [1,2], environmental monitoring [3], precision agriculture [4], automated meter reading [5], indoor localization [6], smart grid [7] and predictive maintenance [8].Several physical layers (PHYs) exist, each finding a different trade-off between energy consumption, datarate and range. Applications for low-power wireless technology are numerous, including smart building [1,2], environmental monitoring [3], precision agriculture [4], automated meter reading [5], indoor localization [6], smart grid [7] and predictive maintenance [8]. One interesting development in low-power wireless technology is the standardization in 2016 of the IEEE802.15.4g amendment [9], which defines additional. IEEE802.15.4g defines PHY specifications initially for smart metering utility networks. Multiplexing—OFDM), data rate ranging from 25 kbps to 800 kbps, and two frequency bands (sub-GHz and 2.4 GHz). These options result in a large set of combinations to address a wide variety of applications, from small home installations [11] to kilometer-scale smart agriculture deployments [12]
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