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2024 | OriginalPaper | Buchkapitel

Securing Wireless Communications in IoT: A Study of One-Step Majority Logic Decodable Codes for Physical Layer Security

verfasst von : Otmane El Mouaatamid, Mohamed Lahmer, Mostafa Belkasmi, Karim Rkizat

Erschienen in: Artificial Intelligence for Sustainable Energy

Verlag: Springer Nature Singapore

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Abstract

Wireless communication networks for the Internet of Things (IoT) system face significant challenges in terms of reliability and security. Traditional networks rely on cryptographic protocols to address security, which primarily focus on upper layers in the OSI model without considering the physical layer. However, recent research has increasingly focused on physical layer security, as it offers a different approach to achieving secrecy in communication. The goal of physical layer security is to ensure that data transmission between legitimate nodes in a network remains confidential, even in the presence of malicious actors attempting to intercept the communication. One way to achieve secrecy is by utilizing the unique characteristics of the physical layer, such as thermal noise, interference, and fading channels. There are various approaches to physical layer security, and this paper focuses on information-theoretic methods for enhancing wireless system security against eavesdropping attacks. Error-correcting codes (ECC) also play a role in providing security, and various code classes can be employed for this purpose, such as polar codes and low-density parity-check (LDPC) codes. In this paper, we investigate the use of One-Step Majority Logic Decodable (OSMLD) codes in physical layer security for IoT applications. OSMLD codes are characterized by their low complexity in the majority decoding process. The main contributions of this work are the application of different types of OSMLD codes in the wiretap channel and the demonstration of the benefits of OSMLD codes in physical layer security for IoT applications.

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Al-Fuqaha, A., Guizani, M., Mohammadi, M., Aledhari, M., Ayyash, M.: Internet of things: a survey on enabling technologies, protocols, and applications. IEEE Comm. Surveys Tut. 17(4), 2347–2376 (2015) (Fourth quarter)

Shannon, C.E.: Communication theory of secrecy systems. Bell Syst. Tech. J. 28, 656–715 (1949)MathSciNetCrossRef

El Mouaatamid, O., Lahmer, M., Belkasmi, M.: Internet of Things Security: Layered classification of attacks and possible countermeasures. Elect. J. Info. Techn. 9 (2016)

Wyner, A.D.: The wire-tap channel. Bell Syst. Tech. J. 54(8), 1355–1387 (1975)MathSciNetCrossRef

Klinc, D., Ha, J., McLaughlin, S., Barros, J., Kwak, B.J.: LDPC codes for physical layer security. In: IEEE Global Telecommunications Conference GLOBECOM (2009)

Klinc, D., Ha, J., McLaughlin, S., Barros, J., Kwak, B.J.: LDPC codes for the Gaussian wiretap channel. IEEE Trans. Inf. Forensics Secur. 6(3), 532–540 (2011)CrossRef

Baldi, M., Bianchi, M., Chiaraluce, F.: Non-systematic codes for physical layer security. In: IEEE Information Theory Workshop, Ireland, Dublin (2010)

Baldi, M., Bianchi, M., Chiaraluce, F.: Coding with scrambling, concatenation, and HARQ for the AWGN wire-tap channel: security gap analysis. IEEE Trans. Inf. Forensics Secur. 7(3), 883–894 (2012)CrossRef

McEliece, R.J.: A public-key cryptosystem based on algebraic coding theory. DSN Prog. Rep. 44, 114–116 (1978)

10.

Baldi, M., Maturo, N., Ricciutelli, G., Chiaraluce, F.: Security gap analysis of some physical layer security for the internet of things based on one-step majority logic decodable codes 11 LDPC coded transmission schemes over the at and fast fading Gaussian wiretap channels. EURASIP. J. Wirel. Commun. 1, 1–12 (2015)

11.

Reed, I.S.: A class of multiple-error-correcting codes and their decoding scheme. IRE Trans. Inf. Th. pGIT-4, 38–49 (1954)

12.

Weldon, E., Jr.: Difference-set cyclic codes. Bell Syst. Tech. J. 45(7), 1045–1055 (1966)MathSciNetCrossRef

13.

El Mouaatamid, O., Lahmer, M., Belkasmi, M.: Construction and decoding of OSMLD codes derived from unital and oval designs. In: 2018 International Conference on Advanced Communication Technologies and Networking (CommNet), pp. 1–7. IEEE (2018)

14.

Rkizat, K., Lahmer, M., Belkasmi, M., Nouh, S.: Construction and iterative thresh-old decoding for low rates quasi-cyclic one step majority logic decodable codes. In: Advanced Communication Systems and Information Security (ACOSIS), International Conference on, pp. 1–7, IEEE (2016)

15.

Belkasmi, M., Lahmer, M., Ayoub, F.: Iterative threshold decoding of product codes constructed from majority logic decodable codes. In: 2006 2nd International Conference on Information and Communication Technologies, Vol. 2, pp. 2376–2381. IEEE (2006)

16.

Green, J.H., San Soucie, R.L.: An error-correcting encoder and decoder of high efficiency. Proc. IRE 46(10), 1741–1744 (1958)CrossRef

17.

Prange, E.: The Use of Coset Equivalence in the Analysis and Decoding of Group Codes, No. AFCRC-tr-59-164. Air Force Cambridge Research Labs Hanscom AFB (1959).

18.

Massey, J.L.: Threshold decoding. No. tr-410. Massachusetts Inst of Tech Cambridge Research Lab of Electronics (1963)

19.

Costello, D.J.: Error Control Coding: Fundamentals and Applications. Prentice Hall (1983)

20.

Csiszar, I., Korner, J.: Broadcast channels with confidential messages. IEEE Trans. Inf. Theory 24(3), 339 (1978)MathSciNetCrossRef

21.

Rkizat, K., Yatribi, A., Lahmer, M., Belkasmi, M.: Iterative threshold decoding of hig rates quasi-cyclic OSMLD codes. Int. J. Adv. Comp. Sci. Appl. 7 (2016)

22.

Belkasmi, M., Lahmer, M., Benchrifa, M.: Iterative threshold decoding of parallel concatenated block codes. In: 4th International Symposium on Turbo Codes and Related Topics; 6th International ITG- Conference on Source and Channel Coding, pp.1–4. VDE (2006)

Titel: Securing Wireless Communications in IoT: A Study of One-Step Majority Logic Decodable Codes for Physical Layer Security
verfasst von: Otmane El Mouaatamid
Mohamed Lahmer
Mostafa Belkasmi
Karim Rkizat
Verlag: Springer Nature Singapore
Buch: Artificial Intelligence for Sustainable Energy
Print ISBN: 978-981-9998-32-6

Electronic ISBN: 978-981-9998-33-3

Copyright-Jahr: 2024
DOI: https://doi.org/10.1007/978-981-99-9833-3_10