Abstract
The use of Wi-Fi-enabled devices is increasing every year. Current consumer demands are related to the requirements for greater rate, greater reliability and greater energy efficiency. In the proposed chapter, studies of signal code construction (SCC) used in Wi-Fi standards: 802.11ac and 802.11ax were carried out. Aspects of beamforming and the use of LDPC codes in robust implementations are described. The relevance of the work is to create recommendations for the use of LDPC and their implementation using the hardware description language (HDL). The chapter focuses on the concept of building an LDPC decoder within the Norm-Min-Sum algorithm in HDL. Recommendations for the efficient use of LDPC-based SCC for 802.11 applications are presented. LDPC codes are popular because they have very good performance and allow for simple hardware implementations. The proposed results will be useful for optimizing signal selection for modern network applications.
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References
Chen Y-M et al (2019) An efficient construction strategy for near-optimal variable-length error-correcting codes. IEEE Commun Lett 23(3):398–401
Abdulkhaleq NI et al (2023) A Simulink model for modified fountain codes. TELKOMNIKA Telecommun Comput El Control 21(1):18–25
Su B-S, Lee C-H, Chiueh T-D (2022) A 58.6/91.3 pJ/b dual-mode belief-propagation decoder for LDPC and polar codes in the 5G communications standard. IEEE Solid State Circ Lett 5:98–101
Boiko J, Eromenko O (2018) Signal processing in telecommunications with forward correction of errors. Indones J Electr Eng Comput Sci 11(3):868–877
Roberts MK, Anguraj PA (2021) Comparative review of recent advances in decoding algorithms for low-density parity-check (LDPC) codes and their applications. Arch Comput Methods Eng 28:2225–2251
Boiko J, Pyatin I, Eromenko O (2021) Design and evaluation of the efficiency of channel coding LDPC codes for 5G information technology. Indones J Electr Eng Inf 9(4):867–879
Liu D et al (2022) An LDPC encoder architecture with up to 47.5 Gbps throughput for DVB-S2/S2X standards. IEEE Access 10:19022–19032
Zhang Y, Jiang M (2023) Genetic optimization of 5G-NR LDPC codes for lowering the error floor of BICM systems. Phys Commun 58:102009
Bae J et al (2019) An overview of channel coding for 5G NR cellular communications. APSIPA Trans Sig Inf Process 8(1):E17
Lee S et al (2019) Dynamic channel bonding algorithm for densely deployed 802.11ac networks. IEEE Trans Commun 67(12):8517–8531
Malekzadeh M, Ghani AAA (2019) 3-sector cell vs. omnicell: cell sectorization impact on the performance of side-by-side unlicensed LTE and 802.11ac air interfaces. IEEE Access 7:122315–122329
Boudaoud A, El Haroussi M, Abdelmounim E (2017) VHDL design and FPGA ımplementation of LDPC decoder for high data rate. Int J Adv Comput Sci Appl 8(4):257-261
Farhan IM, Zaghar DR, Abdullah HN (2022) FPGA implementation of raptor coded DS-CDMA for wireless sensor networks in low SNR regime. 2022 2nd International conference on electronic and electrical engineering and intelligent system (ICE3IS). IEEE Press, Yogyakarta, pp 258–263
Lv Z (2019) Construction of check matrix for B-LDPC and non-binary LDPC codes. In: Liang Q, Mu J, Jia M, Wang W, Feng X, Zhang B (eds) Communications, signal processing, and systems. CSPS 2017. Lecture notes in electrical engineering, vol 463. Springer, Singapore
Praveena H, Kalyani K (2018) FPGA implementation of parity check matrix based low density parity check decoder. 2018 2nd international conference on inventive systems and control (ICISC). IEEE Press, Coimbatore, pp 1214–1217
Sulek W (2010) Banyan switch applied for LDPC decoder FPGA implementation. IFAC Proc Vol 43(24):1–6
Pyatin I, Boiko J, Eromenko O (2021) Evaluating the productivity of HDL efficient coding models for 5G ınformation networks. 2021 IEEE 8th international conference on problems of ınfocommunications, science and technology (PIC S&T). IEEE Press, Kharkiv, pp 305–308
Xu H, Shi W, Sun Y (2023) Performance analysis and design of quasi-cyclic LDPC codes for underwater magnetic induction communications. Phys Commun 56:101950
Zhu Q, Wu L (2013) Weighted-bit-flipping-based sequential scheduling decoding algorithms for LDPC codes. Math Probl Eng 2013:371206
Boiko J, Pyatin I, Karpova L, Eromenko O (2021) Study of the influence of changing signal propagation conditions in the communication channel on bit error rate. In: Data-centric business and applications. Lecture notes on data engineering and communications technologies, vol 69. Springer, Cham, pp 79–103
Pyatin I, Boiko J, Eromenko O, Parkhomey I (2023) Implementation and analysis of 5G network identification operations at low signal-to-noise ratio. TELKOMNIKA Telecommun Comput El Control 21(3):496–505
Tang BY, Liu B, Yu WR et al (2021) Shannon-limit approached information reconciliation for quantum key distribution. Quantum Inf Process 20:113
Shreelatha GU, Kavyashree MK (2023) IEEE 802.11g wireless protocol standard: performance analysis. In: Joby PP, Balas VE, Palanisamy R (eds) IoT based control networks and ıntelligent systems. Lecture notes in networks and systems, vol 528. Springer, Singapore
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Boiko, J., Pyatin, I., Eromenko, O., Karpova, L. (2024). Evaluation of the Capabilities of LDPC Codes for Network Applications in the 802.11ax Standard. In: Joby, P.P., Alencar, M.S., Falkowski-Gilski, P. (eds) IoT Based Control Networks and Intelligent Systems. ICICNIS 2023. Lecture Notes in Networks and Systems, vol 789. Springer, Singapore. https://doi.org/10.1007/978-981-99-6586-1_25
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DOI: https://doi.org/10.1007/978-981-99-6586-1_25
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