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International Journal of Sensors, Wireless Communications and Control

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ISSN (Print): 2210-3279
ISSN (Online): 2210-3287

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Research Article

Reduction of Peak Average Power Ratio for FBMC Waveform with P-PTS Technique

Author(s): Hemant Rathore and Arun Kumar*

Volume 10, Issue 1, 2020

Page: [47 - 54] Pages: 8

DOI: 10.2174/2210327909666190207155619

Price: $65

Abstract

Background: In this work, Peak Average Power Ratio (PAPR) reduction is achieved in Filter Bank Multi-Carrier (FBMC) by using a Pretreated Partial Transmit Sequence (P-PTS) technique. High PAPR is seen as unitary of the major problems in FBMC.

Aims: The proposed work present a double stage optimization technique termed P-PTS.

Methods: In the first step, several overlying signals cooperative optimization method that the phase angle sequences of current signal is intended and improved according to preceding overlapped signals. An efficient PTS scheme for PAPR reduction is put through in the second form.

Results: The suggested technique is carried out by changing the value of U and V to analyze the BER and PAPR performance of the system. It is likewise noted that increasing the value of V can significantly lessen the peak power.

Conclusion: Simulation results reveal that the performance of the proposed P-PTS technique is better than conventional PAPR reduction techniques with simple computations and the design complication can be traded off further compliantly with PAPR diminution.

Keywords: O-QAM-FBMC, OFDM, P-PTS, PAPR, 4G, optimization.

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[1]
Wang B, Wang K, Lu Z, Xie T, Quan J. Comparison study of non-orthogonal multiple access schemes for 5G Int Symp IEEE Broadband Multimed Syst Broadcast. BMSB 2015; pp. 1-5.
[2]
Dai L, Wang Z, Yang Z. Next-generation digital television terrestrial broadcasting systems: key technologies and research trends. IEEE Commun Mag 2012; 50: 150-8.
[3]
Berardinelli G, Pajukoski K, Lahetkangas E, Wichman R, Tirkkonen O, Mogensen P. On the potential of OFDM enhancements as 5G wave forms. In Vehicular Tech Conf (VTC Spring), IEEE 2014; 1-5.
[4]
Zhang H. Filter Bank based MultiCarrier (FBMC) for cognitive radio systems. Netw Internet Architect 2011; pp. 1-151. [https://tel.archives-ouvertes.fr/tel-00628956/document]
[5]
FP7-ICT - specific programme "cooperation": information and communication technologies. Spain, 2015.https://cordis.europa.eu/docs/projects/cnect/2/318362/080/deliverables/
[6]
Zeumann A. 5th generation non-orthogonal waveforms for asynchronous signalling. Deutschland 2015.http://5gnow.eu/?page_id=266
[7]
Chang RW. Synthesis of band-limited orthogonal signals for multichannel data transmission. The Bell Syst Tech J 1966; 1775-96.
[8]
Sezginer S, Sari H. OFDM peak power reduction with simple amplitude pre-distortion. IEEE Commun Lett 2006; 10: 65-7.
[9]
Gokkul A, Kumar A, Kumar H, et al. Performance improvement of OFDM using hybrid PAPR reduction technique. Proc 4th Int Conf Comput, Commun Netw Tech (ICCCNT’13) 2013; 4-6.
[10]
Abbas A, Gasser S, Aziz A, et al. A new approach for PAPR reduction of OFDM signal based on SLM and PTS. Proc 3rd Int Conf e-Tech Netw Develop (ICeND’14) 2014; 58-63.
[11]
Kumar A, Gupta M. A novel modulation technique for 5G mobile communication system. Am J Appl Sci 2015; 12: 601-5.
[12]
Zhou Y, Jiang T, Huang C, et al. Peak-to-average power ratio reduction for OFDM/OQAM signals via alternative-signal method. IEEE Trans Vehicular Technol 2014; 63: 494-9.
[13]
Lu SX, Qu DM, He YJ. Sliding window tone reservation technique for the peak-to-average power ratio reduction of FBMC-OQAM signals. IEEE Wirel Commun Lett 2012; 1: 268-73.
[14]
Varghese N, Chunkath J, Sheeba VS. Peak-to-average power ratio reduction in FBMC-OQAM system. Proc 4th Int Conf Adv Comput Commun (ICACC’14) 2014; 286-90.
[15]
Skrzypczak A, Javaudin JP, Siohan P. Reduction of the peak-toaverage power ratio for the OFDM/OQAM modulation. Proc 63rd Vehicular Tech Conf (VTC-Spring’06). 2006; 4:: 7-10.
[16]
Bulusu K, Shaiek H, Roviras D, et al. Reduction of PAPR for FBMC-OQAM systems using dispersive SLM technique. Proc 11th Int Conf Wireless Commun Syst (ISWCS’14) 2014; 568-72.
[17]
Ye C, Li ZJ, Jiang T, et al. PAPR reduction of OQAM-OFDM signals using segmental PTS scheme with low complexity. IEEE Trans Broadcast 2014; 60: 141-7.
[18]
Le Floch B, Alard M, Berrou C. Coded orthogonal frequency division multiplex. Proc IEEE 1995; 83: 982-96.
[19]
Ochiai H, Imai H. On the distribution of the peak-to-average power ratio in OFDM signals. IEEE Trans Commun 2001; 49: 282-9.
[20]
Al-Dalakta E, Al-Dweik A, Hazmi A, et al. Efficient BER reduction technique for nonlinear OFDM transmission using distortion prediction. IEEE Trans Vehicular Technol 2012; 61: 2330-6.
[21]
Kumar A, Gupta M. Reduction of PAPR by using clipping and filtering for different modulation schemes. Am J Appl Sci 2015; 13: 131-4.
[22]
Sahin A, Guvenc I, Arslan H. A survey on multicarrier communications: prototype filters, lattice structures, and implementation aspects. IEEE Comm Surv Tutor 2014; 16: 1312-38.
[23]
Krongold BS, Jones DL. PAPR reduction in OFDM via active constellation extension. IEEE Trans Broadcast 2003; 49: 258-68.
[24]
Lekouaghet B, Himeur Y, Boukabou A, Senouci A. A novel clipping based μ-law companding scheme for PAPR reduction over power line communication Seminar Detect Sys Architect Technol. DAT 2017; pp. 1-7.
[25]
Lekouaghet B, Himeur Y, Boukabou A, Senouci A. A novel clipping based μ-law companding scheme for PAPR reduction over power line communication Seminar Detect Syst Architect Tech. DAT 2017; pp. 1-7.
[26]
Shaheen I, Zekry A, Newagy F, Ibrahim R. PAPR reduction for FBMC/OQAM using hybrid scheme of different Precoding transform and mu-law companding. Int J Engr Tech 2017; 6: 154-62.
[27]
Fukumizu K, Bach FR, Jordan MI. Kernel dimension reduction in regression. The Annals Statistics 2009; 37: 1871-905.
[28]
Armstrong J. Peak-to-average power reduction for OFDM by repeated clipping and frequency domain filtering. IEEE Electr Lett 2002; 38: 246-7.
[29]
Bulusu SKC, Shaiek H, Roviras D. Reducing the PAPR in FBMC-OQAM systems with low-latency trellis-based SLM technique. EURASIP J Adv Signal Process 2016; 1: 132-7.
[30]
Lim DW, Heo SJ, No JS, Chung H. A new PTS OFDM scheme with low complexity for PAPR reduction. IEEE Trans Broadcast 2006; 52: 77-82.
[31]
Kim H, Rautio T. Weighted selective mapping algorithm for FBMC-OQAM systems IEEE Int Conf Info Commun Tech Converg. ICTC 2016; pp. 214-9.
[32]
Liu K, Hou J, Zhang P, Liu Y. PAPR reduction for FBMC-OQAM systems using P-PTS scheme. The J China Universities Posts TeleCommun 2015; 22: 78-85.
[33]
Kumar A, Rathore H. Reduction of PAPR in FBMC system using different reduction techniques. J Optical Commun 2018. [Epub ahead of print]
[http://dx.doi.org/10.1515/joc-2018-0071.]
[34]
Moeko Y, Hiromichi N, Teruyuki M. PTS Based PAPR reduction by iterative P-Norm minimization without side information in OFDM systems. IEICE Trans Commun 2018; 101: 856-64.
[35]
Harris K, Nasser Y, El Mokdad H, Kabalan KY, Jaffal Y. Are side-band tones beneficial for PAPR reduction in FBMC. 16th IEEE Int Workshop Signal Process Adv Wireless Commun (SPAWC) 2015; 111-5.

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