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2024 | OriginalPaper | Buchkapitel

Communication in IoT Devices

verfasst von : Dipak Wajgi, Jitendra V. Tembhurne, Rakhi Wajgi, Tapan Jain

Erschienen in: Modern Approaches in IoT and Machine Learning for Cyber Security

Verlag: Springer International Publishing

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Abstract

Communication in the wireless network is a backbone for performing the network tasks. Recently, Internet of Things (IoT) devices are used to remotely monitor the system’s performance. Small-sized, smart sensing IoT devices are utilized in wireless network for this purpose. These devices are energy constrained, have less processing power, are used to sense the required environmental parameters, and communicate to the base station via Internet. Sometimes, these devices are communicating with each other for sharing the gathered information. This communication should be efficient enough to collect maximum information in the network. Hence, better communication among the devices leads to the superior performance of the network. Moreover, throughput of the network can be increased by uninterrupted and quality of service (QoS) communication among the devices. To establish a perfect communication anywhere, IoT uses communication technology. There exist various standard communication protocols for wireless network to exchange the information. This chapter provides the role and applicability of different communication protocols used in IoT devices under IoT ecosystem. Furthermore, we also present the comparison of a variety of communication protocols utilized in wireless network based on their behavior, coverage range, power consumption, and other related features. Finally, we suggest the direction and guidelines for selecting an appropriate communication protocol for IoT devices in different applications.

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Vorheriges Kapitel IoT Design Methodology: Architectures and Protocols

Nächstes Kapitel IoT Security and Privacy

P. Sethi, S.R. Sarangi, Internet of Things: architectures, protocols, and applications. J. Electr. Comput. Eng. 2017, 1 (2017)CrossRef

A.H. Ngu, M. Gutierrez, V. Metsis, S. Nepal, Q.Z. Sheng, IoT middleware: A survey on issues and enabling technologies. IEEE Internet Things J. 4(1), 1–20 (2016)CrossRef

M. Mukherjee, I. Adhikary, S. Mondal, A.K. Mondal, M. Pundir, V. Chowdary, A vision of IoT: applications, challenges, and opportunities with Dehradun perspective, in Proceeding of International Conference on Intelligent Communication, Control and Devices, (Springer, Singapore, 2017), pp. 553–559CrossRef

D. Dragomir, L. Gheorghe, S. Costea, A. Radovici, A survey on secure communication protocols for IoT systems, in 2016 International Workshop on Secure Internet of Things (SIoT), (IEEE, September 2016), pp. 47–62CrossRef

S. Tayeb, S. Latifi, Y. Kim, A survey on IoT communication and computation frameworks: An industrial perspective, in 2017 IEEE 7th Annual Computing and Communication Workshop and Conference (CCWC), (IEEE, January 2017), pp. 1–6

G.A. Akpakwu, B.J. Silva, G.P. Hancke, A.M. Abu-Mahfouz, A survey on 5G networks for the Internet of Things: communication technologies and challenges. IEEE Access 6, 3619–3647 (2017)CrossRef

A.A. Zaidan, B.B. Zaidan, M.Y. Qahtan, O.S. Albahri, A.S. Albahri, M. Alaa, et al., A survey on communication components for IoT-based technologies in smart homes. Telecommun. Syst. 69(1), 1–25 (2018)CrossRef

P.P. Ray, A survey on Internet of Things architectures. J. King Saud Univ. Comput. Inf. Sciences 30(3), 291–319 (2018)

L. Chettri, R. Bera, A comprehensive survey on Internet of Things (IoT) toward 5G wireless systems. IEEE Internet Things J. 7(1), 16–32 (2019)CrossRef

10.

J. Dizdarević, F. Carpio, A. Jukan, X. Masip-Bruin, A survey of communication protocols for internet of things and related challenges of fog and cloud computing integration. ACM Comput. Surv. (CSUR) 51(6), 1–29 (2019)CrossRef

11.

Y. Chen, M. Li, P. Chen, S. Xia, Survey of cross-technology communication for IoT heterogeneous devices. IET Commun. 13(12), 1709–1720 (2019)CrossRef

12.

B. Nour, K. Sharif, F. Li, S. Biswas, H. Moungla, M. Guizani, Y. Wang, A survey of Internet of Things communication using ICN: a use case perspective. Comput. Commun. 142, 95–123 (2019)CrossRef

13.

C.C. Sobin, A survey on architecture, protocols and challenges in IoT. Wirel. Pers. Commun. 112, 1–47 (2020)CrossRef

14.

D. Dutta, IEEE 802.15. 4 as the mac protocol for internet of things (IoT) applications for achieving QoS and energy efficiency, in Advances in Communication, Cloud, and Big Data, (Springer, Singapore, 2019), pp. 127–132CrossRef

15.

T. Paso, V. Niemelä, J. Haapola, M. Hämäläinen, J. Iinatti, Performance evaluation of IEEE 802.15. 4-2011 IR-UWB system with enhanced modulation scheme, in Proceedings of the 10th EAI International Conference on Body Area Networks, (September 2015), pp. 116–122

16.

J.W. Hui, D.E. Culler, Extending IP to low-power, wireless personal area networks. IEEE Internet Comput. 12(4), 37–45 (2008)CrossRef

17.

J. Park, S. Lee, S.H. Bouk, D. Kim, Y. Hong, 6LoWPAN adaptation protocol for IPv6 packet transmission over NFC device, in 2015 Seventh International Conference on Ubiquitous and Future Networks, (IEEE, July 2015), pp. 541–543CrossRef

18.

N. Mirza, A.N. Khan, Bluetooth low energy based communication framework for intra vehicle wireless sensor networks, in 2017 International Conference on Frontiers of Information Technology (FIT), (IEEE, December 2017), pp. 29–34CrossRef

19.

E. Mackensen, M. Lai, T.M. Wendt, Bluetooth Low Energy (BLE) based wireless sensors, in SENSORS, 2012 IEEE, (IEEE, October 2012), pp. 1–4

20.

P. Narendra, S. Duquennoy, T. Voigt, BLE and IEEE 802.15. 4 in the IoT: evaluation and interoperability considerations, in International Internet of Things Summit, (Springer, Cham, October 2015), pp. 427–438

21.

D. Sembroiz, S. Ricciardi, D. Careglio, A novel cloud-based IoT architecture for smart building automation, in Security and Resilience in Intelligent Data-Centric Systems and Communication Networks, (Academic Press, 2018), pp. 215–233CrossRef

22.

S. Arvind, V.A. Narayanan, An overview of security in CoAP: attack and analysis, in 2019 5th International Conference on Advanced Computing & Communication Systems (ICACCS), (IEEE, March 2019), pp. 655–660CrossRef

23.

I. Ishaq, J. Hoebeke, F. Van den Abeele, I. Moerman, P. Demeester, Group communication in constrained environments using CoAP-based entities, in 2013 IEEE International Conference on Distributed Computing in Sensor Systems, (IEEE, May 2013), pp. 345–350CrossRef

24.

T. Adiono, R. Muttaqin, R.M. Rahayu, R.V.W. Putra, Cloud system design using AMQP protocol for smart devices system applications (2020)

25.

M. Lebiedz, Advanced Message Queuing Protocol (AMQP) as a communication protocol standard for IoT, ppt

26.

M. Elezi, B. Raufi, Conception of Virtual Private Networks using IPsec suite of protocols, comparative analysis of distributed database queries using different IPsec modes of encryption. Procedia Soc. Behav. Sci. 195, 1938–1948 (2015)CrossRef

27.

IP Security Protocol, https://cdn.ttgtmedia.com/searchEnterpriseLinux/downloads/Kozierok_Ch29.pdf. Accessed on 9th Oct 2020

28.

M. Song, Z. Yun-he, One new research about IPSec communication based on HTTP tunnel, in 2009 IEEE International Symposium on Parallel and Distributed Processing with Applications, (IEEE, August 2009), pp. 253–257CrossRef

29.

A. Lavric, A.I. Petrariu, LoRaWAN communication protocol: the new era of IoT, in 2018 International Conference on Development and Application Systems (DAS), (IEEE, May 2018), pp. 74–77CrossRef

30.

A. Lavric, V. Popa, Performance evaluation of LoRaWAN communication scalability in large-scale wireless sensor networks. Wirel. Commun. Mob. Comput. 2018, 1 (2018)CrossRef

31.

M.A. Ertürk, M.A. Aydın, M.T. Büyükakkaşlar, H. Evirgen, A survey on LoRaWAN architecture, protocol and technologies. Futur. Internet 11(10), 216 (2019)CrossRef

32.

R.P. Jover, I. Murynets, Connection-less communication of IoT devices over LTE mobile networks, in 2015 12th Annual IEEE International Conference on Sensing, Communication, and Networking (SECON), (IEEE, June 2015), pp. 247–255CrossRef

33.

N. Saxena, S. Grijalva, N.S. Chaudhari, Authentication protocol for an IoT-enabled LTE network. ACM Trans. Internet Technol. (TOIT) 16(4), 1–20 (2016)CrossRef

34.

M.B. Yassein, M.Q. Shatnawi, S. Aljwarneh, R. Al-Hatmi, Internet of Things: Survey and open issues of MQTT protocol, in 2017 International Conference on Engineering & MIS (ICEMIS), (IEEE, May 2017), pp. 1–6

35.

D. Dinculeană, X. Cheng, Vulnerabilities and limitations of MQTT protocol used between IoT devices. Appl. Sci. 9(5), 848 (2019)CrossRef

36.

M. Kashyap, V. Sharma, N. Gupta, Taking MQTT and NodeMcu to IOT: Communication in Internet of Things. Proc. Comput. Sci. 132, 1611–1618 (2018)CrossRef

37.

K. Fan, C. Zhang, K. Yang, H. Li, Y. Yang, Lightweight NFC protocol for privacy protection in mobile IoT. Appl. Sci. 8(12), 2506 (2018)CrossRef

38.

A. Asaduzzaman, S. Mazumder, S. Salinas, M.F. Mridha, A security-aware near field communication architecture, in 2017 International Conference on Networking, Systems and Security (NSysS), (IEEE, January 2017), pp. 33–38CrossRef

39.

D. He, N. Kumar, J.H. Lee, Secure pseudonym-based near field communication protocol for the consumer internet of things. IEEE Trans. Consum. Electron. 61(1), 56–62 (2015)CrossRef

40.

Y.L. Dos Santos, E. Dias Canedo, On the design and implementation of an IoT based architecture for reading ultra high frequency tags. Information 10(2), 41 (2019)CrossRef

41.

S. Hadjer, C.E.Y. Mustapha, R. Touhami, Role and application of RFID technology in Internet of Things: Communication, authentication, risk, and security concerns. ISeCure ISC Int. J. Inf. Secur. 11(3), 9–17 (2019)

42.

X. Jia, Q. Feng, T. Fan, Q. Lei, RFID technology and its applications in Internet of Things (IoT), in 2012 2nd International Conference on Consumer Electronics, Communications and Networks (CECNet), (IEEE, April 2012), pp. 1282–1285CrossRef

43.

A. Varghese, D. Tandur, A. Ray, Suitability of WiFi based communication devices in low power industrial applications, in 2017 IEEE International Conference on Industrial Technology (ICIT), (IEEE, March 2017), pp. 1307–1312CrossRef

44.

H. Wang, D. Xiong, P. Wang, Y. Liu, A lightweight XMPP publish/subscribe scheme for resource-constrained IoT devices. IEEE Access 5, 16393–16405 (2017)CrossRef

45.

A. Iivari, T. Väisänen, M. Ben Alaya, T. Riipinen, T. Monteil, Harnessing xmpp for machine-to-machine communications & pervasive applications. J. Commun. Softw. Syst. 10(3), 163–178 (2014)CrossRef

46.

İ. Ünal, Integration of ZigBee based GPS receiver to CAN network for precision farming applications. Peer-to-Peer Netw. Appl. 13, 1–12 (2020)CrossRef

47.

J.S. Lee, Y.M. Wang, Experimental evaluation of ZigBee-based wireless networks in indoor environments. J. Eng. 2013, 286–367 (2013)

48.

C.W. Badenhop, S.R. Graham, B.W. Ramsey, B.E. Mullins, L.O. Mailloux, The Z-wave routing protocol and its security implications. Comput. Secur. 68, 112–129 (2017)CrossRef

49.

M.B. Yassein, W. Mardini, A. Khalil, Smart homes automation using Z-wave protocol, in 2016 International Conference on Engineering & MIS (ICEMIS), (IEEE, September 2016), pp. 1–6

50.

J. Zhu, L. Huo, M.D. Ansari, M.A. Ikbal, Research on data security detection algorithm in IoT based on K-means. Scale. Comput. Pract. Exp. 22(2), 149–159 (2021)

51.

L. Ting, M. Khan, A. Sharma, M.D. Ansari, A secure framework for IoT-based smart climate agriculture system: toward blockchain and edge computing. J. Intell. Syst. 31(1), 221–236 (2022)

52.

A. Vijayakrishna, G. Gopichand, M.D. Ansari, G. Suryanarayana, IOT based smart agriculture using LIFI, in 2022 5th International Conference on Multimedia, Signal Processing and Communication Technologies (IMPACT), (IEEE, November 2022), pp. 1–7

Titel: Communication in IoT Devices
verfasst von: Dipak Wajgi
Jitendra V. Tembhurne
Rakhi Wajgi
Tapan Jain
Verlag: Springer International Publishing
Buch: Modern Approaches in IoT and Machine Learning for Cyber Security
Print ISBN: 978-3-031-09954-0

Electronic ISBN: 978-3-031-09955-7

Copyright-Jahr: 2024
DOI: https://doi.org/10.1007/978-3-031-09955-7_2

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