Abstract
The massive Multiple-Input and Multiple-Output Orthogonal Frequency Division Multiplexing (MIMO–OFDM) system provides a high data transmission for the next generation mobile communication i.e. 4G, 5G, etc. In the practical MIMO–OFDM system, N points of IFFT/FFT is larger than M data subcarriers (\(N>M\)) in each OFDM symbol to reject the aliasing after D/A converter. To demodulate information data, the channel responses for all MIMO channel links need to be estimated so as to employ in MIMO data detection for demodulation at the receiver. The discrete Fourier transform estimator (DFE) was proposed for the system which can estimate the MIMO channels accurately when \(N=M\). However, its accuracy will be hugely degraded when \(N>M\) because of the oversampling of data transmission. To improve the estimation accuracy when \(N>M\), the maximum likelihood estimator (MLE) was proposed for the system which can achieve higher estimation accuracy than that of the DFE. However, its accuracy will be degraded a lot in the massive MIMO–OFDM system when \(N>M\), due to the estimation error increased in proportion to the increasing of \(N_T\) transmit antennas. To solve these problems, this paper proposes a direct time-domain estimator (DTE) with preamble symbol with scattered-pilot (preamble-SCP) for the massive MIMO–OFDM system when \(N>M\). In the proposed method, it is presented with three salient features; achieving higher estimation accuracy with keeping almost the same computational complexity as the conventional estimators, improving \(Bit-Error-Rate\) (BER) with low-complexity MIMO data detection, and providing higher transmission data rate compared with the MLE. Using the \(normalized\,MSE\), BER and throughput evaluated by computer simulations, it can be verified that the proposed DTE with preamble-SCP obviously provides higher estimation accuracy, better BER with low-complexity MIMO data detection, and much higher transmission data rate which is approximately 32.5 Mbps gain over the MLE at 5 MHz-BW respectively.
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References
ETSI EN 300 744 v1.6.2 (2015-10)
ETSI EN 302 755 v1.4.1 (2015-07)
Mobile WiMAX - Part 1: A Technical Overview and Performance Evaluation, WiMAX Forum, 2006.
Nee, R. V., Jones, V. K., Awater, G., Zelst, A. V., Gardner, J., & Steele, G. (2006). The 802.11n MIMO–OFDM standard for wireless LAN and beyond. Wireless Personal Communication, 37, 445–453.
Frenzel, L. E. (2013). An introduction to LTE-advanced: the real 4G, Electronic design, pp. 32–38.
Li, Y. G., Winters, J. H., & Sollenberger, N. R. (2002). MIMO-OFDM for wireless communications: Signal detection with enhanced channel estimation. IEEE Transactions on Communications, 50(9), 1471–1477.
Sure, P., & Bhuma, C. M. (2015). A pilot aided channel estimator using DFT based time interpolation for massive MIMO–OFDM systems. AEU International Journal of Electronics and Communications, 69(1), 321–327.
Technologies, Vehicular. (2011). M. Diallo, M. Helard, L. Cariou, R. Rabineau, DFT based channel estimation methods for MIMO-OFDM systems, InTech. Increasing Connectivity, 97–114.
Mata, T., Naito, K., Boonsrimuang, P., Mori, K., & Kobayashi, H. (2014). Proposal of channel estimation method for ITS systems by using STBC MIMO–OFDM. ECTI Transactions on Computer and Information Technology, 8(1), 36–44.
Kobayashi, H., & Mori, K. (2005). Proposal of OFDM channel estimation method using Discrete Cosine Transform. IEICE Transaction on Communication (Japanese edition), J88–B(2), 256–268.
Jariwala, P.P., & Lapsiwala, P. (2013). Review: Performance Evolution of Different Detection Techniques in V-BLAST. in Proceeding of the 4th International Conference on Computing, Communications and Networking Technologies (ICCCNT2013), pp. 1–5.
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. IEEE Electronics Letter, 35(1), 14–16.
Mohaisen, M., An, H., & Chang, K. H. (2009). Detection techniques for MIMO multiplexing: A comparative review. KSII Transactions on Internet and Information Systems, 3(6), 647–666.
Lu, H.-Y., Yen, M.-H., & Chen, B.-S. (2018). Fast group detection for massive MIMOs. IET Communications, 12(13), 1602–1608.
Soria, V., Arévalo, G. V., Ávila, P., Tello, F., & Santamaría, C. G. (2018). Performance comparison of \(2\times 2\) and \(4\times 4\) V-BLAST and Alamouti MIMO systems. IEEE Third Ecuador Technical Chapters Meeting (ETCM), pp. 1–4.
Larson, E. G. (2009). MIMO detection methods: How they work. IEEE Signal Processing Magazine, 26(3), 91–95.
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Mata, T., Boonsrimuang, P. An Effective Channel Estimation for Massive MIMO–OFDM System. Wireless Pers Commun 114, 209–226 (2020). https://doi.org/10.1007/s11277-020-07359-2
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DOI: https://doi.org/10.1007/s11277-020-07359-2