Chapter 7 - IoT protocols, architectures, and applications

Chiara Buratti; Erik Ström; Luca Feltrin; Laurent Clavier; Gordana Gardašević; Thomas Blazek; Lazar Berbakov; Titus Constantin Balan; Luis Orozco-Barbosa; Carles Anton-Haro; Piotr Rajchowski; Haibin Zhang

doi:https://doi.org/10.1016/B978-0-12-820581-5.00013-4

Chapter 7 - IoT protocols, architectures, and applications

Chiara Buratti, Erik Ström, Luca Feltrin, Laurent Clavier, Gordana Gardašević, Thomas Blazek, Lazar Berbakov, Titus Constantin Balan, Luis Orozco-Barbosa, Carles Anton-Haro, Piotr Rajchowski, Haibin Zhang

Wireless Communications (WLC)

Research output: Conference proceeding/Chapter in Book/Report/ › Chapter

Abstract

The proliferation of embedded systems, wireless technologies, and Internet protocols have made it possible for the Internet-of-things (IoT) to bridge the gap between the physical and the virtual world and thereby enabling monitoring and control of the physical environment by data processing systems. IoT refers to the inter-networking of everyday objects that are equipped with sensing, computing, and communication capabilities. These networks can collaborate to autonomously solve a variety of tasks. Due to the very diverse set of applications and application requirements, there is no single communication technology that is able to provide cost-effective and close to optimal performance in all scenarios. In this chapter, we report on research carried out on a selected number of IoT topics: low-power wide-area networks, in particular, LoRa and narrow-band IoT (NB-IoT); IP version 6 over IEEE 802.15.4 time-slotted channel hopping (6TiSCH); vehicular antenna design, integration, and processing; security aspects for vehicular networks; energy efficiency and harvesting for IoT systems; and software-defined networking/network functions virtualization for (SDN/NFV) IoT.

Original language	English
Title of host publication	Inclusive Radio Communications for 5G and Beyond
Editors	Claude Oestges, François Quitin
Pages	187-220
Number of pages	34
DOIs	https://doi.org/10.1016/B978-0-12-820581-5.00013-4
Publication status	Published - 1 Jan 2021

Publication series

Name	Inclusive Radio Communications for 5G and Beyond

Keywords

6TiSCH
Energy efficiency
Energy harvesting
Experimental measurements
IEEE 802.15.4
IEEE 802.25.4e
Industry 4.0
Internet of Things
Internet Protocol version 6
Joint scheduling and routing
LoRa
LoRaWAN
Low power wide area networks
Machine type communication
Management and orchestration
Medium Access Control protocols
Mobile Network Operator
Narrow Band-IoT
Network function virtualization
Open Mote
Open WSN
Radio access technologies
Received signal strength indicator
Round trip time
Routing protocol for low power and lossy networks
Routing protocols
Signal to interference ratio
Signal to noise ratio
Simultaneous wireless information and power transfer
Smart environments
Software defined networking
Software defined radio
Source routing
Spreading factor
Time slotted channel hopping
Vehicular applications
Vehicular communications

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https://doi.org/10.1016/B978-0-12-820581-5.00013-4

https://www.sciencedirect.com/science/article/pii/B9780128205815000134

Cite this

Buratti, C., Ström, E., Feltrin, L., Clavier, L., Gardašević, G., Blazek, T., Berbakov, L., Balan, T. C., Orozco-Barbosa, L., Anton-Haro, C., Rajchowski, P., & Zhang, H. (2021). Chapter 7 - IoT protocols, architectures, and applications. In C. Oestges, & F. Quitin (Eds.), Inclusive Radio Communications for 5G and Beyond (pp. 187-220). (Inclusive Radio Communications for 5G and Beyond). https://doi.org/10.1016/B978-0-12-820581-5.00013-4

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Buratti, C, Ström, E, Feltrin, L, Clavier, L, Gardašević, G, Blazek, T, Berbakov, L, Balan, TC, Orozco-Barbosa, L, Anton-Haro, C, Rajchowski, P & Zhang, H 2021, Chapter 7 - IoT protocols, architectures, and applications. in C Oestges & F Quitin (eds), Inclusive Radio Communications for 5G and Beyond. Inclusive Radio Communications for 5G and Beyond, pp. 187-220. https://doi.org/10.1016/B978-0-12-820581-5.00013-4

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AU - Blazek, Thomas

AU - Berbakov, Lazar

AU - Balan, Titus Constantin

AU - Orozco-Barbosa, Luis

AU - Anton-Haro, Carles

AU - Rajchowski, Piotr

AU - Zhang, Haibin

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AB - The proliferation of embedded systems, wireless technologies, and Internet protocols have made it possible for the Internet-of-things (IoT) to bridge the gap between the physical and the virtual world and thereby enabling monitoring and control of the physical environment by data processing systems. IoT refers to the inter-networking of everyday objects that are equipped with sensing, computing, and communication capabilities. These networks can collaborate to autonomously solve a variety of tasks. Due to the very diverse set of applications and application requirements, there is no single communication technology that is able to provide cost-effective and close to optimal performance in all scenarios. In this chapter, we report on research carried out on a selected number of IoT topics: low-power wide-area networks, in particular, LoRa and narrow-band IoT (NB-IoT); IP version 6 over IEEE 802.15.4 time-slotted channel hopping (6TiSCH); vehicular antenna design, integration, and processing; security aspects for vehicular networks; energy efficiency and harvesting for IoT systems; and software-defined networking/network functions virtualization for (SDN/NFV) IoT.

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KW - Energy harvesting

KW - Experimental measurements

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KW - Internet Protocol version 6

KW - Joint scheduling and routing

KW - LoRa

KW - LoRaWAN

KW - Low power wide area networks

KW - Machine type communication

KW - Management and orchestration

KW - Medium Access Control protocols

KW - Mobile Network Operator

KW - Narrow Band-IoT

KW - Network function virtualization

KW - Open Mote

KW - Open WSN

KW - Radio access technologies

KW - Received signal strength indicator

KW - Round trip time

KW - Routing protocol for low power and lossy networks

KW - Routing protocols

KW - Signal to interference ratio

KW - Signal to noise ratio

KW - Simultaneous wireless information and power transfer

KW - Smart environments

KW - Software defined networking

KW - Software defined radio

KW - Source routing

KW - Spreading factor

KW - Time slotted channel hopping

KW - Vehicular applications

KW - Vehicular communications

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Chapter 7 - IoT protocols, architectures, and applications

Abstract

Publication series

Keywords

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