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Wireless Personal Communications

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26.08.2020

Comparative Study on Implementation Performance Analysis of Simulink Models of Cognitive Radio Based GFDM and UFMC Techniques for 5G Wireless Communication

verfasst von: Manisha Gupta, Ankur Singh Kang, Vishal Sharma

Erschienen in: Wireless Personal Communications | Ausgabe 1/2022

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Abstract

In this paper, we studied different reduction methods for peak to average power ratio (PAPR) and bit error rate (BER) in generalized frequency division multiplexing (GFDM) and universal filtered multicarrier (UFMC) as well as the relation between UFMC and GFDM on the basis of PAPR and BER for different windowing techniques in cognitive radio for future wireless communication systems. With the help of MATLAB as well as Simulink model, we have discussed all the conclusions related to GFDM and UFMC parameters in a Comparative manner. Recently a lot of work is going on next generation i.e. fifth generation (5G). In this, generalized frequency division multiplexing and universal filtered multicarrier are the two most favourable candidates which fulfil all the requirements which are necessary for present situation. The comparative analysis done between UFMC and GFDM schemes in terms of robustness against multipath channels shows that the simulation results obtained have a deep impact on study of performance analysis of multicarrier modulation techniques implemented through Simulink models in a ubiquitous and pervasive scenario.

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Fagbohun, O. O. (2014). A comparative studies on 3G, 4G and 5G wireless technology. IOSR Journal of Electronics and Communication Engineering, 9(3), 88–94.

www.electronicsnotes.com. Accessed 2016.

Hameed Ansari, A., & Gulhane, S. M. (2015) Cyclostationary method based spectrum sensing and analysing using different windowing methods. In International conference on energy systems and applications (pp. 684–688).

Chen, A. C. (1998). Advances in wireless communications technologies and their potential biomedical applications. In IEEE international conference on information technology applications in biomedicine (pp. 82–84).

Bhalla, M. R., & Bhalla, A. V. (2010). Generations of mobile wireless technology: A survey. International Journal of Computer Applications, 5(4), 26–32.CrossRef

Rahnema, M. (1993). Overview of the GSM system and protocol architecture. IEEE Communications, 31(4), 92–100.CrossRef

Salkintzis, A. K., Fors, C., & Pazhyannur, R. (2002). WLAN-GPRS integration for next-generation mobile data networks. IEEE Wireless Communications, 9(5), 112–124.CrossRef

Bettstetter, C., Vogel, H. J., & Eberspacher, J. (1999). GSM phase 2 + general packet radio service GPRS: Architecture, protocols, and air interface. IEEE Communications Surveys, 2(3), 2–14.CrossRef

Furuskar, A., Frodigh, M., Olofsson, H., & Skold, J. (1998). System performance of EDGE, a proposal for enhanced data rates in existing digital cellular systems. In IEEE vehicular technology conference. Pathway to global wireless revolution (pp. 1284–1289).

10.

Chuang, J., & Sollenberger, N. (2000). Beyond 3G: wideband wireless data access based on OFDM and dynamic packet assignment. IEEE Communications Magazine, 38(7), 78–87.CrossRef

11.

Jindal, S., & Jindal, A. (2005). Grouping WI-MAX, 3G and WI-FI for wireless broadband. In 1st IEEE international conference in Central Asia on Internet (p. 5).

12.

Garber, L. (2002). Will 3G really be the next big wireless technology. Computer, 35(1), 26–35.MathSciNetCrossRef

13.

Honkasalo, H., & Pehkonen, K. (2002). WCDMA and WLAN for 3G and beyond. IEEE Wireless Communications, 9(2), 14–18.CrossRef

14.

Choi, M. G., & Xu, Y. (2000). A new multimedia network architecture using 3G CDMA2000. In Vehicular Technology Conference Fall 2000. IEEE VTS Fall VTC2000. 52nd vehicular technology conference (Vol. 6, pp. 2937–2944).

15.

Krenik, B. (2008) 4G wireless technology: When will it happen? What does it offer? In IEEE Asian solid-state circuits conference (pp. 141–144).

16.

Zhen, L. (2002). Consideration: Research issues for future generation of mobile communication. Proceedings of IEEE CCECE, 3, 1276–1281.

17.

Frattasi, S., Fathi, H., & Fitzek, F. (2006). Defining 4G technology from the users perspective. IEEE Network, 20(1), 35–41.CrossRef

18.

Khan, A. H., Qadeer, M. A., et.al. (2009). 4G as a next generation wireless network. In International conference on future computer communication.

19.

Wang, X. (2005). OFDM and its application to 4G. In 14th annual international conference on wireless and optical communication (p. 69).

20.

Sasipriya, S., & Vigneshram, R. (2016). An overview of cognitive radio in 5G wireless communications. In IEEE international conference on computational intelligence and computing research (pp. 1–5).

21.

Mitola, J., & Maguire, G. Q. (1999). Cognitive radio: Making software radios more personal. IEEE Personal Communications Magazine, 6(4), 13–18.CrossRef

22.

Arul, U. S., & Ranjan, S. S. C. (2016). Spectrum management techniques using cognitive radios technology. International Journal of Data Mining Techniques and Applications, 5(1), 79–82.CrossRef

23.

Lu, L., Zhou, X., Onunkwo, U., & Li, G. Y. (2012). Ten years of research in spectrum sensing and sharing in cognitive radio. EURASIP Journal on Wireless Communication and Networking, 2012, 28. https://doi.org/10.1186/1687-1499-2012-28.CrossRef

24.

Ansari, A. H., & Gulhane, S. M. (2018). Next generation wireless communicationm system using windowing techniques. International Journal of Students’ Research in Technology & Management, 16, 2.

25.

Sattorov, M., Yeo, S. S., & Jo-Kang, H. (2011). Pros and Cons of multi user orthogonal frequency division multiplexing. (pp. 4).

26.

Kumar, A., & Santosh, S. (2018). Next generation wireless communication system. International Journal of Students’ Research in Technology & Management, 6, 12.

27.

Datta, R., Michailow, N., Lentmaier, M., Fettweis, G. (2012) Analysis of spectrum sensing characteristics for cognitive radio GFDM signal. In IEEE publication (pp. 356–359).

28.

Fettweis, G., Krondrof, M., & Bittner, S. (2009). GFDM generalized frequency division multiplexing. In Proceedings of Vehicle Technology Conference (pp. 1–4).

29.

Datta, R., Michailow, N., Lentmaier, M., Fettweis, G. (2012). GFDM interference cancellation for flexible cognitive radio PHY design. In IEEE vehicular technology conference (VTC Fall) (pp. 1–5).

30.

Vakilian, V., Wild, T., Schaich, F., Brink, S., & Frigon, J. F. (2013). Universal-filtered multi-carrier technique for wireless systems beyond LTE. In IEEE Globecom workshops (pp. 223–228).

31.

Wunder, G., Kasparick, M., ten Brink, S., et al. (2013). 5GNOW: challenging the LTE design paradigms of orthogonality and synchronicity. In Vehicular technology conference (VTC Spring) (pp. 1–5). IEEE.

32.

Schaich, F., & Wild, T. (2014) Waveform contenders for 5G—OFDM vs. FBMC vs. UFMC. In 6th international symposium on communications, control and signal processing (ISCCSP).

33.

Wild, T., Schaich, F., & Yejian, C. (2014). 5G air interface design based on Universal Filtered (UF-) OFDM. In 19th international conference on digital signal processing (DSP) (pp. 699–704).

34.

Cho, H., Yan, Y., Chang, G. K., & Ma, X. (2017). Asynchronous multi-user uplink transmissions for 5G with UFMC waveform. In IEEE wireless communications and networking conference (WCNC) (pp. 1–5).

35.

Chen, Y., Schaich, F., Wild, T. (2014). Multiple access and waveforms for 5G: IDMA and Universal Filtered Multi-Carrier. In Proceedings of IEEE 79th vehicular technology conference (VTC Spring) (pp. 1–5).

36.

Rani, P., Baghla, S., & Monga, H. (2017). Hybrid PAPR reduction scheme for universal filter multi-carrier modulation in next generation wireless systems. Research & Development in C Material Science, 17(4), 22–33.

37.

Bauml, R. W., Fischer, R. F. H., & Huber, J. B. (1996). Reducing the peak to average power ratio of multi carrier modulation by selected mapping. IEEE Electronics Letters, 32(22), 2056–2057.CrossRef

38.

Zhang, Y., Liu, K., & Liu, Y. (2018). A novel PAPR reduction algorithm based on SLM technique in UFMC systems. In IEEE/CIC international conference on communications in China (ICCC workshops) (pp. 178–183).

39.

Li, X., & Cimini, L. J. (1998). Effects of clipping and filtering on the performance of OFDM. IEEE Communications Letters, 2(5), 131–133.CrossRef

40.

Jebbar, H., & El Hassani, S. (2018). PAPR reduction for 5G waveform. In 6th international conference on wireless networks mobile communication.

41.

Krongold, B.S., Jones, D. L. (2002) A new tone reservation method for complex baseband PAR reduction in OFDM system. In IEEE international conference acoustics, speech and signal processing (ICASSP) (Vol. 3, pp. III-2321–III-2324).

42.

Wang, X., Tjhung, T. T., & Ng, C. S. (1999). Reduction of peak to average power ratio of OFDM system using a companding technique. IEEE Transactions on Broadcasting, 25, 420–422.CrossRef

43.

Ren, S., Liu, B., Zhang, L., Xin, X., Ullah, R. (2017) A random filtering mapping method for PAPR reduction based on generalized frequency division multiplexing. In 16th international conference on optical communications and networks (pp. 1–3).

44.

Sharifian, Z., Omidi, Md. J., Farhang, A., & Sourck, H. S. (2015). Polynomial-based compressing and iterative expanding for PAPR reduction in GFDM. In Iranian conference on electrical engineering (pp. 518–523).

45.

Liu, K., Deng, W., & Liu, Y. (2018). An efficient nonlinear companding transform method for PAPR reduction of GFDM signals. In 2018 IEEE/CIC international conference on communications in China (ICCC) (pp. 460–464).

46.

Sourck, H. S., Sharifian, Z., Omidi, Md J, & Farhang, A. (2016). Linear Precoding for PAPR reduction of GFDMA. IEEE Wireless Communications Letters, 5, 520–523.CrossRef

47.

Sendrei, L., Marchevsky, S. (2014). Iterative receiver for clipped GFDM signals. In 24th international conference Radioelektronika (pp. 1–4).

48.

Zhong, Z., & Guo, J. (2016). Bit error rate analysis of a MIMO-generalized frequency division multiplexing scheme for 5th generation cellular systems. In IEEE international conference on electronic information and communication technology (pp. 62–68).

49.

www.rfwireless-world.com. Accessed 2016.

50.

Wang, H., & Zhang, Z. (2017). UFMC transmission with active interference cancellation. IEEE, 65(6), 2554–2567.

51.

Wei, P., & Xia, X. (2016) Low-complexity DGT-based GFDM receiver in broadband channels. In IEEE international conference on communication system (p. 6).

52.

Datta, R., Fettweis, G., Kollar, Z., & Horvath, P. (2011). FBMC and GFDM interference cancellation schemes for flexible digital radio PHY design. In 14th EUROMICRO conference (Euromicro’11) (pp. 335–339).

53.

Kang, A. S., Sharma, V., & Gupta, M. (2018). GFDM and UFMC modulation techniques under dispersive wireless channels for cognitive radio-a technical review. International Journal of Research, 16(1), 11.

54.

Wu, M., Dang, J., & Zhang, Z. (2018). An advanced receiver for universal filtered multicarrier. IEEE, 67(8), 7779–7783.

55.

Wang, X., Wild, T., Schaich, F., & Fonseca dos Santos, A. (2014). Universal filtered multi-carrier with leakage-based filter optimization. In 20th European Wireless Conference (pp. 1–5).

56.

Kang, A. S., Gupta, M., & Sharma, V. (2020). Comparative performance analysis of GFDM and UFMC techniques in cognitive radio under the effect of different windowing techniques for next generation communication. International Journal of Information Technology, 12(2), 10.

Titel: Comparative Study on Implementation Performance Analysis of Simulink Models of Cognitive Radio Based GFDM and UFMC Techniques for 5G Wireless Communication
verfasst von: Manisha Gupta
Ankur Singh Kang
Vishal Sharma
Publikationsdatum: 26.08.2020
Verlag: Springer US
Erschienen in: Wireless Personal Communications / Ausgabe 1/2022
Print ISSN: 0929-6212
Elektronische ISSN: 1572-834X
DOI: https://doi.org/10.1007/s11277-020-07561-2

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