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Wireless Personal Communications

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10-08-2020

Performances of OSIC Detector of an UpLink OFDM Massive-MIMO System in Rayleigh and Ricain Fading Channels

Authors: Abdelhamid Riadi, Mohamed Boulouird, Moha M’Rabet Hassani

Published in: Wireless Personal Communications | Issue 3/2020

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Abstract

This paper presents a least squares channel estimation for Massive-Multiple-Input Multiple- Output (Massive-MIMO) systems in next generation of wireless communications denominated 5G, combined with Orthogonal Frequency Division Multiplexing (OFDM) and 64-QAM modulation. In this paper, after determining the estimated channel, we first consider one OFDM symbol and presented the flat fading and the frequency-selective fading in the case when channel taps equal to one and strictly superior to one respectively. In addition to that, we consider the uplink transmission where the transmitter antenna equal to \(N_t=50\) and a Base Station (BS) equipped with several antenna superior to that of transmitter, in the same way the data detected using a linear detectors Zero-Forcing and Minimum Mean Square Error. Moreover we improve their performance by an ordered successive interference cancellation (OSIC) method. Using two channels fading namely the Rayleigh and the Ricain respectively and evaluate their performance with a system of Massive-MIMO antenna. Increasing the number of channel taps increase the inter-symbol interference allows to degrade the performance of the system both the Rayleigh and Rician channel, even we used a pilot sequence equipowered, equispaced and phase shift orthogonal. Hence increasing the number of antennas arrays at the receiver (i.e BS) decreases more the Bit Error Rate, consequently increasing the performance of the system. the OSIC methods provide a best performance when the number of antenna grow in a smaller range of Signal-to-Noise Ratio.

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Larsson, E. G., Edfors, O., Tufvesson, F., & Marzetta, T. L. (2014). Massive MIMO for next generation wireless systems. IEEE Communications Magazine, 52(2), 186–195.

Chockalingam, A., & Rajan, B. S. (2014). Large MIMO systems. Cambridge: Cambridge University Press.

Rusek, F., Persson, D., Lau, B. K., Larsson, E. G., Marzetta, T. L., Edfors, O., et al. (2013). Scaling up MIMO: Opportunities and challenges with very large arrays. IEEE Signal Processing Magazine, 30(1), 40–60.CrossRef

Singh, S., et al. (2016). Review of DFT based channel estimation techniques in OFDM over multipath channel. International Journal of Recent Research Aspects., 3(4), 8–11.

Jaldén, N., Zetterberg, P., Ottersten, B., Hong, A., & Thoma, R. (2007). Correlation properties of large scale fading based on indoor measurements. In Wireless Communications and Networking Conference, 2007. WCNC 2007 (pp. 1894–1899). IEEE.

Ashikhmin, A., Marzetta, T. L., & Li, L. (2014) Interference reduction in multi-cell massive MIMO systems I: Large-scale fading precoding and decoding. IEEE Transactions on Information Theory.

de Figueiredo, F. A. P., Cardoso, F. A. C. M., Moerman, I., & Fraidenraich, G. (2018). Channel estimation for massive MIMO TDD systems assuming pilot contamination and flat fading. EURASIP Journal on Wireless Communications and Networking, 1, 14.CrossRef

Ohlmer, E., & Fettweis, G. (2010). Linear and non-linear detection for MIMO-OFDM systems with linear precoding and spatial correlation. IEEE Wireless Communications and Networking Conference (WCNC), 1, 1–6.

Shen, C., Zhu, Y., Zhou, S., & Jiang, J. (2004). On the performance of V-BLAST with zero-forcing successive interference cancellation receiver. IEEE Global Telecommunications Conference GLOBECOM, 5, 2818–2822.CrossRef

10.

Han, J., Tao, X., & Cui, Q. (2009). Lower bound of BER in M-QAM MIMO system with ordered ZF-SIC receiver. In IEEE 69th Vehicular Technology Conference, VTC Spring 2009 (pp. 1–5).

11.

Maung, S. M., Hajime, S., & Iwao, S. (2012) Reduced complexity scheme for MIMO receiver with combined ZF-OSIC and ML detection. In IEEE Symposium on Computers & Informatics (ISCI), 2012 (pp. 92–96).

12.

Wang, J., Wen, O. Y., Li, S. (2007) Soft-output MMSE OSIC MIMO detector with reduced-complexity approximations. In IEEE 8th Workshop on Signal Processing Advances in Wireless Communications (pp. 1–5).

13.

Wang, J., & Li, S. (2008) Soft-output MIMO MMSE OSIC detector under MMSE channel estimation. In Third International Conference on IEEE Communications and Networking in China, 2008 (pp. 1117–1121).

14.

Song, Y., Liu, C., & Lu, F. (2016). The optimal MMSE-based OSIC detector for MIMO system. IEICE Transactions on Communications, 99(1), 232–239.CrossRef

15.

Ngo, H. Q., Larsson, E. G. & Marzetta, T. L. (2013) Energy and spectral efficiency of very large multiuser MIMO systems. IEEE Transactions on Communications. 61(4):1436–1449

16.

Cho, Y. S., Kim, J., Yang, W. Y., & Kang, C. G. (2010). MIMO-OFDM wireless communications with MATLAB. New York: Wiley.CrossRef

17.

Murthy, P. N., & Satyanarayana, R. V. S. (2010). A comparison of rayleigh and rician fading channels under frequency-selective fading. IUP Journal of Electrical & Electronics Engineering, 3(4), 1.

18.

Moradi, A., Bakhshi, H., & Najafpoor, V. (2011). Pilot placement for time-varying MIMO OFDM channels with virtual subcarriers. Communications and Network, 3(1), 31.CrossRef

19.

Barhumi, I., Leus, G., & Moonen, M. (2003). Optimal training design for MIMO OFDM systems in mobile wireless channels. IEEE Transactions on Signal Processing, 51(6), 1615–1624.CrossRef

20.

Cantrell, C. D. (2000). Modern mathematical methods for physicists and engineers. Cambridge: Cambridge University Press.MATHCrossRef

21.

Tung, T.-L., Yao, K., & Hudson, R. E. (2001) Channel estimation and adaptive power allocation for performance and capacity improvement of multiple-antenna OFDM systems. In In IEEE 3rd Workshop on Signal Processing Advances in Wireless Communications (SPAWC’01) Workshop Proceedings (pp. 82–85).

22.

Yang, S., & Hanzo, L. (2015). Fifty years of MIMO detection: The road to large-scale MIMOs. IEEE Communications Surveys & Tutorials, 17(4), 1941–1988.CrossRef

23.

Rajeev, P., Prabhat, A., & Norsang, L. (2014). Sphere Detection Technique: An Optimum Detection Scheme for MIMO System. International Journal of Computer Applications, 100(2), 1.CrossRef

24.

Foschini, G. J. (1996). Layered space-time architecture for wireless communication in a fading environment when using multi-element antennas. Bell Labs Technical Journal, 1(2), 41–59.CrossRef

25.

Golden, G. D., Foschini, C. J., Valenzuela, R. A., & Wolniansky, P. W. (1999). Detection algorithm and initial laboratory results using V-BLAST space-time communication architecture. Electronics Letters, 35(1), 14–16.CrossRef

26.

Wolniansky, P. W., Foschini, G. J., Golden, G. D., & Valenzuela, R. A. (1998) V-BLAST: An architecture for realizing very high data rates over the rich-scattering wireless channel. In URSI International Symposium on Signals, Systems, and Electronics, 1998, ISSSE 98 (pp. 295–300).

Title: Performances of OSIC Detector of an UpLink OFDM Massive-MIMO System in Rayleigh and Ricain Fading Channels
Authors: Abdelhamid Riadi
Mohamed Boulouird
Moha M’Rabet Hassani
Publication date: 10-08-2020
Publisher: Springer US
Published in: Wireless Personal Communications / Issue 3/2020
Print ISSN: 0929-6212
Electronic ISSN: 1572-834X
DOI: https://doi.org/10.1007/s11277-020-07670-y

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