Research Article
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PAPR reduction using selective mapping scheme in universal filtered multicarrier waveform

Year 2020, Volume: 4 Issue: 3, 233 - 238, 15.12.2020
https://doi.org/10.35860/iarej.730126

Abstract

In this paper, the selective mapping (SLM) technique possessing the powerful and distortionless peak to average power ratio (PAPR) reduction capability was employed in universal filtered multicarrier (UFMC) waveform that is considered as one of the most promising fifth generation (5G) waveform candidates in order to provide a solution to the PAPR issue encountered in the related waveform. Owing to our SLM-based PAPR reduction implementation performed by employing the SLM scheme between the quadrate amplitude modulation (QAM) mapping and bandwidth-subdivision operations at the transmitter side, successful PAPR reduction results were achieved in a straightforward and effective manner. In the simulations, the effect of the related way of SLM application on alleviating the PAPR and spectral leakages of the UFMC signal amplified via the solid state power amplifier (SSPA) was investigated for various number of phase factor combinations. Besides, the impact of SLM on the bit error rate (BER) of the UFMC waveform was analyzed for varied values of SSPA parameters called smoothness (p) and input back off (IBO) controlling the linearity and operation point of the SSPA, respectively.

Supporting Institution

Scientific Research Projects Coordination Unit of Erciyes University

Project Number

FDK-2018-8463

References

  • 1. Vakilian, V., T. Wild, F. Schaich, S.T. Brink, and J.F. Frigon, Universal-filtered multi-carrier technique for wireless systems beyond LTE, in GC Wkshps 2013: Atlanta. p. 223-228.
  • 2. Li, Y., B. Tian, K. Yi, and Q. Yu, A novel hybrid CFO estimation scheme for UFMC-based systems. IEEE Communications Letters, 2017. 21(6): p. 1337-1340.
  • 3. Wu, M., J. Dang, Z. Zhang, and L. Wu, An advanced receiver for universal filtered multicarrier. IEEE Transactions on Vehicular Technology, 2018. 67(8): p. 7779-7783.
  • 4. Duan, S., X. Yu, and R. Wang, Performance analysis on filter parameters and sub-bands distribution of universal filtered multi-carrier. Wireless Personal Communications, 2017. 95(3): p. 2359-2375.
  • 5. Chen, J.C. and C.K. Wen, PAPR reduction of OFDM signals using cross-entropy-based tone injection schemes. IEEE Signal Processing Letters, 2010. 17(8): p. 727-730.
  • 6. Krongold, B.S. and D.L. Jones, PAR reduction in OFDM via active constellation extension. IEEE Transactions on Broadcasting, 2003. 43(3): p. 258-268.
  • 7. Bauml, R.W., R.F.H. Fischer, and J.B. Huber, Reducing the peak-to-average power ratio of multicarrier modulation by selected mapping. Electronics Letters, 1996. 32(22): p. 2056-2057.
  • 8. Wang, C.L. and Y. Quyang, Low-complexity selected mapping schemes for peak-to-average power ratio reduction in OFDM systems. IEEE Transactions on Signal Processing, 2005. 53(12): p. 4652-4660.
  • 9. Liang, H., H.C. Chu, and C.B. Lin, Peak-to-average power ratio reduction of orthogonal frequency division multiplexing systems using modified tone reservation techniques. International Journal of Communication Systems, 2016. 29(4): p. 748-759.
  • 10. Li, X. and L.J. Cimini, Effect of clipping and filtering on the performance of OFDM. IEEE Communications Letters, 1998. 2(5): p. 131-133.
  • 11. Jones A.E., T.A. Wilkinson, and S.K. Barton, Block coding scheme for reduction of peak to mean envelope power ratio of multicarrier transmission scheme. Electronics Letters, 1994. 30(25): p. 2098-2099.
  • 12. Cimini, L.J. and N.R. Sollenberger, Peak-to-average power ratio reduction of an OFDM signal using partial transmit sequences. IEEE Communications Letters, 2000. 4(3): p. 86-88.
  • 13. Bozkurt, Y.T. and N. Taşpınar, PAPR reduction performance of bat algorithm in OFDM systems. International Advanced Researches and Engineering Journal, 2019. 3(3): p. 150-155.
  • 14. Jayalath, A.D.S. and C. Tellambura, Reducing the peak-to-average power ratio of orthogonal frequency division multiplexing signal through bit or symbol interleaving. Electronics Letters, 2000. 36(13): p. 1161-1163.
  • 15. Baig, I., U. Farooq, N.U. Hasan, M. Zghaibeh, A. Sajid, and U.M. Rana, A low PAPR DHT precoding based UFMC scheme for 5G communication systems, CoDIT 2019: Paris. p. 425-428.
  • 16. Taşpınar, N. and Ş. Şimşir, PAPR reduction based on partial transmit sequence technique in UFMC waveform, in CISTI 2019: Coimbra. p. 1-6.
  • 17. Tipan, M.N., J. Caceres, M.N. Jimenez, I.N. Cano, and G. Arevalo, Comparison of clipping techniques for PAPR reduction in UFMC systems, LATINCOM 2017: Guatemala City. p. 1-4.
  • 18. Rong, W., J. Cai, and X. Yu, Low-complexity PTS PAPR reduction scheme for UFMC systems. Cluster Computing, 2017. 20(11): p. 3427-3440.
  • 19. Ryu, H.G., J.S. Park, and J.S. Park, Threshold IBO of HPA in the predistorted OFDM communication system. IEEE Transactions on Broadcasting, 2004. 50(4): p. 425-428.
Year 2020, Volume: 4 Issue: 3, 233 - 238, 15.12.2020
https://doi.org/10.35860/iarej.730126

Abstract

Project Number

FDK-2018-8463

References

  • 1. Vakilian, V., T. Wild, F. Schaich, S.T. Brink, and J.F. Frigon, Universal-filtered multi-carrier technique for wireless systems beyond LTE, in GC Wkshps 2013: Atlanta. p. 223-228.
  • 2. Li, Y., B. Tian, K. Yi, and Q. Yu, A novel hybrid CFO estimation scheme for UFMC-based systems. IEEE Communications Letters, 2017. 21(6): p. 1337-1340.
  • 3. Wu, M., J. Dang, Z. Zhang, and L. Wu, An advanced receiver for universal filtered multicarrier. IEEE Transactions on Vehicular Technology, 2018. 67(8): p. 7779-7783.
  • 4. Duan, S., X. Yu, and R. Wang, Performance analysis on filter parameters and sub-bands distribution of universal filtered multi-carrier. Wireless Personal Communications, 2017. 95(3): p. 2359-2375.
  • 5. Chen, J.C. and C.K. Wen, PAPR reduction of OFDM signals using cross-entropy-based tone injection schemes. IEEE Signal Processing Letters, 2010. 17(8): p. 727-730.
  • 6. Krongold, B.S. and D.L. Jones, PAR reduction in OFDM via active constellation extension. IEEE Transactions on Broadcasting, 2003. 43(3): p. 258-268.
  • 7. Bauml, R.W., R.F.H. Fischer, and J.B. Huber, Reducing the peak-to-average power ratio of multicarrier modulation by selected mapping. Electronics Letters, 1996. 32(22): p. 2056-2057.
  • 8. Wang, C.L. and Y. Quyang, Low-complexity selected mapping schemes for peak-to-average power ratio reduction in OFDM systems. IEEE Transactions on Signal Processing, 2005. 53(12): p. 4652-4660.
  • 9. Liang, H., H.C. Chu, and C.B. Lin, Peak-to-average power ratio reduction of orthogonal frequency division multiplexing systems using modified tone reservation techniques. International Journal of Communication Systems, 2016. 29(4): p. 748-759.
  • 10. Li, X. and L.J. Cimini, Effect of clipping and filtering on the performance of OFDM. IEEE Communications Letters, 1998. 2(5): p. 131-133.
  • 11. Jones A.E., T.A. Wilkinson, and S.K. Barton, Block coding scheme for reduction of peak to mean envelope power ratio of multicarrier transmission scheme. Electronics Letters, 1994. 30(25): p. 2098-2099.
  • 12. Cimini, L.J. and N.R. Sollenberger, Peak-to-average power ratio reduction of an OFDM signal using partial transmit sequences. IEEE Communications Letters, 2000. 4(3): p. 86-88.
  • 13. Bozkurt, Y.T. and N. Taşpınar, PAPR reduction performance of bat algorithm in OFDM systems. International Advanced Researches and Engineering Journal, 2019. 3(3): p. 150-155.
  • 14. Jayalath, A.D.S. and C. Tellambura, Reducing the peak-to-average power ratio of orthogonal frequency division multiplexing signal through bit or symbol interleaving. Electronics Letters, 2000. 36(13): p. 1161-1163.
  • 15. Baig, I., U. Farooq, N.U. Hasan, M. Zghaibeh, A. Sajid, and U.M. Rana, A low PAPR DHT precoding based UFMC scheme for 5G communication systems, CoDIT 2019: Paris. p. 425-428.
  • 16. Taşpınar, N. and Ş. Şimşir, PAPR reduction based on partial transmit sequence technique in UFMC waveform, in CISTI 2019: Coimbra. p. 1-6.
  • 17. Tipan, M.N., J. Caceres, M.N. Jimenez, I.N. Cano, and G. Arevalo, Comparison of clipping techniques for PAPR reduction in UFMC systems, LATINCOM 2017: Guatemala City. p. 1-4.
  • 18. Rong, W., J. Cai, and X. Yu, Low-complexity PTS PAPR reduction scheme for UFMC systems. Cluster Computing, 2017. 20(11): p. 3427-3440.
  • 19. Ryu, H.G., J.S. Park, and J.S. Park, Threshold IBO of HPA in the predistorted OFDM communication system. IEEE Transactions on Broadcasting, 2004. 50(4): p. 425-428.
There are 19 citations in total.

Details

Primary Language English
Subjects Electrical Engineering
Journal Section Research Articles
Authors

Şakir Şimşir 0000-0002-1287-160X

Necmi Taşpınar 0000-0003-4689-4487

Project Number FDK-2018-8463
Publication Date December 15, 2020
Submission Date April 30, 2020
Acceptance Date July 6, 2020
Published in Issue Year 2020 Volume: 4 Issue: 3

Cite

APA Şimşir, Ş., & Taşpınar, N. (2020). PAPR reduction using selective mapping scheme in universal filtered multicarrier waveform. International Advanced Researches and Engineering Journal, 4(3), 233-238. https://doi.org/10.35860/iarej.730126
AMA Şimşir Ş, Taşpınar N. PAPR reduction using selective mapping scheme in universal filtered multicarrier waveform. Int. Adv. Res. Eng. J. December 2020;4(3):233-238. doi:10.35860/iarej.730126
Chicago Şimşir, Şakir, and Necmi Taşpınar. “PAPR Reduction Using Selective Mapping Scheme in Universal Filtered Multicarrier Waveform”. International Advanced Researches and Engineering Journal 4, no. 3 (December 2020): 233-38. https://doi.org/10.35860/iarej.730126.
EndNote Şimşir Ş, Taşpınar N (December 1, 2020) PAPR reduction using selective mapping scheme in universal filtered multicarrier waveform. International Advanced Researches and Engineering Journal 4 3 233–238.
IEEE Ş. Şimşir and N. Taşpınar, “PAPR reduction using selective mapping scheme in universal filtered multicarrier waveform”, Int. Adv. Res. Eng. J., vol. 4, no. 3, pp. 233–238, 2020, doi: 10.35860/iarej.730126.
ISNAD Şimşir, Şakir - Taşpınar, Necmi. “PAPR Reduction Using Selective Mapping Scheme in Universal Filtered Multicarrier Waveform”. International Advanced Researches and Engineering Journal 4/3 (December 2020), 233-238. https://doi.org/10.35860/iarej.730126.
JAMA Şimşir Ş, Taşpınar N. PAPR reduction using selective mapping scheme in universal filtered multicarrier waveform. Int. Adv. Res. Eng. J. 2020;4:233–238.
MLA Şimşir, Şakir and Necmi Taşpınar. “PAPR Reduction Using Selective Mapping Scheme in Universal Filtered Multicarrier Waveform”. International Advanced Researches and Engineering Journal, vol. 4, no. 3, 2020, pp. 233-8, doi:10.35860/iarej.730126.
Vancouver Şimşir Ş, Taşpınar N. PAPR reduction using selective mapping scheme in universal filtered multicarrier waveform. Int. Adv. Res. Eng. J. 2020;4(3):233-8.



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