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Wireless Personal Communications
Published in: Wireless Personal Communications 4/2014

01-08-2014

Detection and Mitigation of Impulsive Interference on OFDM Signals Based on Spectrum Sensing, Blanking and Symbol Retransmission

Authors: Giulio Bartoli, Romano Fantacci, Dania Marabissi, Luigia Micciullo, Daniele Tarchi

Published in: Wireless Personal Communications | Issue 4/2014

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Abstract

The increasing number of wireless devices and systems operating on the same area leads to significant interference problems that need to be solved. This paper deals with detection and mitigation of the interference generated by an impulsive noise source on an orthogonal frequency division multiplexing system. The idea proposed here is to overcome the interference problem by exploiting the transmission of two replicas of the symbol affected by interference, that are suitably combined at the receiver after a blanking operation of the corrupted samples. An energy detection based sensing scheme is used to reveal the presence of interference. The proposed method allows to efficiently remove the interference without affecting the useful information and exploiting profitably the diversity gain against noise through the soft combining approach. Performance in terms of bit error rate and throughput is compared with the case without mitigation and with the classical blanking method showing a significant improvement. The reduction of the transmission rate, due to the retransmissions, is well compensated by the improvement of the data reliability that leads to an increase of useful data correctly received.
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Footnotes
1
We assume to have a perfect knowledge of the channel response for equalization purposes.
 
2
The results can be easily extended to a Rayleigh fading channel by averaging the performance with the Rayleigh distribution.
 
3
In general, even if the interference and signal timings are aligned at the beginning of an OFDM symbol, in the next one they will not be synchronized unless \(K\) and \(CP\) are multiples of \(D\).
 
Literature
1.
Zimmermann, M., & Dostert, K. (2002). Analysis and modeling of impulsive noise in broad-band powerline communications. IEEE Transactions on Electromagnetic Compatibility, 44(1), 249–258.CrossRef
2.
Morosi, S., Marabissi, D., Del Re, E., Fantacci, R., & Del Santo, N. (2006). A rate adaptive bit-loading algorithm for in-building power-line communications based on DMT-modulated systems. IEEE Transactions on Power Delivery, 21( 4), 1892–1897.
3.
Budsabathon, M., & Hara, S. (2001). Robustness of OFDM signal against temporally localized impulsive noise. IEEE Vehicular Technology Conference (VTC), 3, 1672–1676.
4.
Ghosh, M. (1996). Analysis of the effect of impulse noise on multicarrier and single carrier QAM systems. IEEE Transaction on Communications, 44, 145–147.CrossRef
5.
Zhidkov, S. V. (2008). Analysis and comparison of several simple impulsive noise mitigation schemes for OFDM receivers. IEEE Transaction on Communications, 56, 5–9.CrossRef
6.
Yong-Hwa, K., Kyong-Hoe, K., Hui-Myoung, O., Kwan-Ho, K., & Seong-Cheol, K. (2008) Mitigation of effect of impulsive noise for OFDM systems over power line channels. In Proceedings IEEE internatinal symposium power line communications and its applications ISPLC, pp. 386–390 (2008).
7.
Saxena, R., & Joshi, H. D. (2013). ICI reduction in OFDM system using IMBH pulse shapes. Wireless Personal Communications, 71(4), 2895–2911.CrossRef
8.
Yih, Chi-Hsiao. (2012). Iterative interference cancellation for OFDM signals with blanking nonlinearity in impulsive noise channels. IEEE Signal Processing Letter, 19(3), 147–150.CrossRef
9.
Haring, J., & Vinck, A. J. H. (2003). Iterative decoding of codes over complex numbers for impulsive noise channels. IEEE Transaction on Information Theory, 49(5), 1251–1260.CrossRefMathSciNet
10.
Zhidkov, S. V. (2003). Impulsive noise suppression in OFDM-based communication systems. IEEE Transactions on Consumer Electronics, 49(4), 944–948.CrossRef
11.
Armstrong, J., & Suraweera, H. A. (2004). Impulse noise mitigation for OFDM using decision directed noise estimation. In IEEE international symposium spread spectrum techniques and applications, pp. 174–178 (2004)
12.
Kitamura, T., Ohno, K., Itami, M. (2011). Iterative impulsive noise reduction by generating its replica signal in OFDM reception. In Proceedings of the IEEE international consumer electronics (ICCE) conference, pp. 389–390 (2011).
13.
Fantacci, R., Tani, A., & Tarchi, D. (2010). Impulse noise mitigation techniques for xDSL systems in a real environment. IEEE Transactions on Consumer Electronics, 56(4), 2106–2114.CrossRef
14.
Torio, P., & Sanchez, M. G. (2012). Cell interleaving against impulsive noise in OFDM. IEEE Transactions on Consumer Electronics, 58(2), 269–273.CrossRef
15.
Yucek, T. & Arslan, H. (2009). A survey of spectrum sensing algorithms for cognitive radio applications. IEEE Communications Surveys and Tutorials, 11(1), 116–130.
16.
Digham, F. F., Alouini, M. S., & Simon, M. K. (2007). On the energy detection of unknown signals over fading channels. IEEE Transaction on Communications, 55(1), 21–24.CrossRef
17.
Cheng, Jung-Fu. (2006). Coding performance of hybrid ARQ schemes. IEEE Transaction on Communications, 54(6), 1017–1029.CrossRef
18.
Blackar, K. L., Rappaport, T. S., & Bostian, C. W. (1993). Measurements and models of radio frequency impulsive noise for indoor wireless communications. IEEE Journal on Selected Areas in Communications, 11, 991–1001.CrossRef
19.
Mann, I., McLaughlin, S., Henkel, W., Kirkby, R., & Kessler, T. (2002). Impulse generation with appropriate amplitude, length, inter-arrival, and spectral characteristics. IEEE Journal on Selected Areas Communications, 20, 901–912.CrossRef
20.
ITU-R (1997). Guidelines for evaluation of radio transmission technologies for IMT-2000. International Telecommunication Union, Recommendation M.1225.
Metadata
Title
Detection and Mitigation of Impulsive Interference on OFDM Signals Based on Spectrum Sensing, Blanking and Symbol Retransmission
Authors
Giulio Bartoli
Romano Fantacci
Dania Marabissi
Luigia Micciullo
Daniele Tarchi
Publication date
01-08-2014
Publisher
Springer US
Published in
Wireless Personal Communications / Issue 4/2014
Print ISSN: 0929-6212
Electronic ISSN: 1572-834X
DOI
https://doi.org/10.1007/s11277-014-1658-6

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