Search search
Publication Date
to
Vol. 3
Latest Volume
All Volumes
PIERB 117 [2026] PIERB 116 [2026] PIERB 115 [2025] PIERB 114 [2025] PIERB 113 [2025] PIERB 112 [2025] PIERB 111 [2025] PIERB 110 [2025] PIERB 109 [2024] PIERB 108 [2024] PIERB 107 [2024] PIERB 106 [2024] PIERB 105 [2024] PIERB 104 [2024] PIERB 103 [2023] PIERB 102 [2023] PIERB 101 [2023] PIERB 100 [2023] PIERB 99 [2023] PIERB 98 [2023] PIERB 97 [2022] PIERB 96 [2022] PIERB 95 [2022] PIERB 94 [2021] PIERB 93 [2021] PIERB 92 [2021] PIERB 91 [2021] PIERB 90 [2021] PIERB 89 [2020] PIERB 88 [2020] PIERB 87 [2020] PIERB 86 [2020] PIERB 85 [2019] PIERB 84 [2019] PIERB 83 [2019] PIERB 82 [2018] PIERB 81 [2018] PIERB 80 [2018] PIERB 79 [2017] PIERB 78 [2017] PIERB 77 [2017] PIERB 76 [2017] PIERB 75 [2017] PIERB 74 [2017] PIERB 73 [2017] PIERB 72 [2017] PIERB 71 [2016] PIERB 70 [2016] PIERB 69 [2016] PIERB 68 [2016] PIERB 67 [2016] PIERB 66 [2016] PIERB 65 [2016] PIERB 64 [2015] PIERB 63 [2015] PIERB 62 [2015] PIERB 61 [2014] PIERB 60 [2014] PIERB 59 [2014] PIERB 58 [2014] PIERB 57 [2014] PIERB 56 [2013] PIERB 55 [2013] PIERB 54 [2013] PIERB 53 [2013] PIERB 52 [2013] PIERB 51 [2013] PIERB 50 [2013] PIERB 49 [2013] PIERB 48 [2013] PIERB 47 [2013] PIERB 46 [2013] PIERB 45 [2012] PIERB 44 [2012] PIERB 43 [2012] PIERB 42 [2012] PIERB 41 [2012] PIERB 40 [2012] PIERB 39 [2012] PIERB 38 [2012] PIERB 37 [2012] PIERB 36 [2012] PIERB 35 [2011] PIERB 34 [2011] PIERB 33 [2011] PIERB 32 [2011] PIERB 31 [2011] PIERB 30 [2011] PIERB 29 [2011] PIERB 28 [2011] PIERB 27 [2011] PIERB 26 [2010] PIERB 25 [2010] PIERB 24 [2010] PIERB 23 [2010] PIERB 22 [2010] PIERB 21 [2010] PIERB 20 [2010] PIERB 19 [2010] PIERB 18 [2009] PIERB 17 [2009] PIERB 16 [2009] PIERB 15 [2009] PIERB 14 [2009] PIERB 13 [2009] PIERB 12 [2009] PIERB 11 [2009] PIERB 10 [2008] PIERB 9 [2008] PIERB 8 [2008] PIERB 7 [2008] PIERB 6 [2008] PIERB 5 [2008] PIERB 4 [2008] PIERB 3 [2008] PIERB 2 [2008] PIERB 1 [2008]
All Journals
PIER PIER B PIER C PIER M PIER Letters
2007-12-29
Frequency Domain Interference Cancellation for Single Carrier Cyclic Prefix CDMA System
By
Faisal Al-Kamali,

    Dr. Faisal Al-Kamali

    Department of Electronics and Electrical Communication Engineering

    Menoufia University

    Egypt

    Homepage

Moawad Ibrahim Dessouky,

    Dr. Moawad Ibrahim Dessouky

    Department of Electronics and Electrical Communication Engineering

    Menoufia University

    Egypt

    Homepage

Basioun Sallam,

    Dr. Basioun Sallam

    Department of Electronics and Electrical Communication Engineering

    Menoufia University

    Egypt

    Homepage

Fathi Abd El-Samie

    Dr. Fathi Abd El-Samie

    Department of Electronics and Electrical Communication Engineering

    Menoufia University

    Egypt

    Homepage

Progress In Electromagnetics Research B, Vol. 3, 255-269, 2008
doi:10.2528/PIERB07121408 | Google Scholar

Abstract
In this paper, we propose a low complexity receiver structure for Single-input Multiple-output (SIMO) downlink cyclic prefix CDMA (CP-CDMA) systems. It employs an interference cancellation scheme to suppress the interference caused by the multipath fading channel. Also, the proposed scheme is developed for Multiple-input Multiple-output (MIMO) CP-CDMA system. All filters in the proposed receiver are implemented in the frequency domain. The performance of the proposed receiver is studied and compared. Our results show a large performance improvement when using such an interference cancellation scheme relative to the rake receiver, and frequency domain Equalization (FDE).
Download Full Article (214) View Full Article volume
Citation
Faisal Al-Kamali, Moawad Ibrahim Dessouky, Basioun Sallam, and Fathi Abd El-Samie, "Frequency Domain Interference Cancellation for Single Carrier Cyclic Prefix CDMA System," Progress In Electromagnetics Research B, Vol. 3, 255-269, 2008.
doi:10.2528/PIERB07121408
References

1. Falconer, D., et al. "Frequency domain equalization for singlecarrier broadband wireless systems," IEEE Common. Mag., Vol. 40, 58-66, April 2002.
doi:10.1109/35.995852        Google Scholar

2. Adachi, F., D. Garge, S. Takaoka, and K. Takeda, "Broadband CDMA techniques," IEEE Wireless Communications, Vol. 12, No. 2, 8-18, April 2005.
doi:10.1109/MWC.2005.1421924        Google Scholar

3. Martoyo, I., T. Wesis, F. Capar, and F. Jondral, "Low complexity CDMA downlink receiver based on frequency domain equalization," Proc. IEEE Vech. Tech. Conf., 987-991, Oct. 2003.        Google Scholar

4. Foschini, G. J., "Layered space-time architecture for wireless communication in a fading environment when using multi-element antennas," Bell Labs Technical Journal, 1996.        Google Scholar

5. Abouda, A. A. and S. G. Haggman, "Effect of coupling on capacity of MIMO wireless channels in high SNR scenario," Progress In Electromagnetic Research, Vol. 65, 27-40, 2006.
doi:10.2528/PIER06072803        Google Scholar

6. Zhu, X. and R. D. Murch, "Novel frequency-domain equalization architectures for a singlecarrier wireless MIMO system," IEEE VTC, Vol. 2, 874-878, Sept. 2002.        Google Scholar

7. Takeda, K., K. Ishihara, and F. Adachi, "Downlink DS-CDMA transmission with joint MMSE equalization and ICI cancellation," IEEE Veh. Technol. Conf., Vol. 4, 1762-1766, 2006.        Google Scholar

8. Alamouti, S. M., "A simple transmit diversity technique for wireless communications," IEEE Journal Selected Areas on Communications, Vol. 16, 1451-1458, Oct. 1998.
doi:10.1109/49.730453        Google Scholar

9. Geyi, W., "Multi-antenna information theory," Progress In Electromagnetics Research, Vol. 75, 11-50, 2007.
doi:10.2528/PIER07052203        Google Scholar

Download Full Article (214) View Full Article volume


The EM Academy piers.org jpier.org Who's Who in EM
Copyright © 2022 The Electromagnetics Academy. All Rights Reserved.