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Abstract
Bluetooth Low Energy (BLE) is increasingly used for time-critical IoT applications, where BLE-based smart objects need to exchange data with a remote server within stringent end-to-end latency and reliability bounds. While existing research has investigated how to timely send packets between pairs of BLE devices, it is still unclear how a BLE device can sustain time-critical end-to-end communication
with a remote server, for example, hosted in the cloud. In this paper, we tackle this problem and show how BLE devices can autonomously measure and cope with end-to-end network delays and loss along the path to the remote server. To this end, we first devise an analytical model of the communication between a BLE end-node and the cloud. We then leverage this model to dynamically adapt the communication parameters of the BLE device and sustain the desired end-to-end dependability requirements while minimizing the energy expenditure. Specifically, we design and implement two adaptation strategies on the popular nRF52 platform, and experimentally show that they both allow to sustain a given end-to-end reliability and a given end-to-end latency for data transmissions from/to the BLE node, while limiting the node’s power consumption.
with a remote server, for example, hosted in the cloud. In this paper, we tackle this problem and show how BLE devices can autonomously measure and cope with end-to-end network delays and loss along the path to the remote server. To this end, we first devise an analytical model of the communication between a BLE end-node and the cloud. We then leverage this model to dynamically adapt the communication parameters of the BLE device and sustain the desired end-to-end dependability requirements while minimizing the energy expenditure. Specifically, we design and implement two adaptation strategies on the popular nRF52 platform, and experimentally show that they both allow to sustain a given end-to-end reliability and a given end-to-end latency for data transmissions from/to the BLE node, while limiting the node’s power consumption.
Originalsprache | englisch |
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Titel | EWSN '21: Proceedings of the 2021 International Conference on Embedded Wireless Systems and Networks |
Seiten | 55-66 |
Seitenumfang | 12 |
ISBN (elektronisch) | 978-0-9949886-5-2 |
Publikationsstatus | Veröffentlicht - 17 Feb. 2021 |
Veranstaltung | 18th International Conference on Embedded Wireless Systems and Networks: EWSN 2021 - Virtuell, Delft, Niederlande Dauer: 17 Feb. 2021 → 19 Feb. 2021 https://ewsn2021.ewi.tudelft.nl/ |
Konferenz
Konferenz | 18th International Conference on Embedded Wireless Systems and Networks |
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Kurztitel | EWSN '21 |
Land/Gebiet | Niederlande |
Ort | Virtuell, Delft |
Zeitraum | 17/02/21 → 19/02/21 |
Internetadresse |
Fields of Expertise
- Information, Communication & Computing
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- 1 Laufend
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Intelligent & Networked Embedded Systems
Boano, C. A., Römer, K. U., Schuß, M., Cao, N., Saukh, O., Hofmann, R., Stocker, M., Schuh, M. P., Papst, F., Salomon, E., Brunner, H., Gallacher, M., Mohamed Hydher, M. H., Wang, D., Corti, F., Krisper, M., Basic, F. & Petrovic, K.
1/09/13 → 31/12/24
Projekt: Arbeitsgebiet
Aktivitäten
- 1 Vortrag bei Konferenz oder Fachtagung
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Ensuring End-to-End Dependability Requirements in Cloud-based Bluetooth Low Energy Applications
Michael Spörk (Redner/in)
17 Feb. 2021Aktivität: Vortrag oder Präsentation › Vortrag bei Konferenz oder Fachtagung › Science to science