FBMC and UFMC Multi-Waveform Design for 6G Wireless Networks
The upcoming sixth-generation (6G) mobile is designed with several purposes, such as incredible improvements, ultra-fast speed, ultra-low latency, and massive connections within a small area. Bandwidth Efficiency and extensive coverage, besides sub-millisecond synchronization using a new sub-terahe...
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| Language: | English |
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University of Diyala
2025-06-01
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| Series: | Diyala Journal of Engineering Sciences |
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| Online Access: | https://djes.info/index.php/djes/article/view/1687 |
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| author | Zhraa Zuheir Yahya Dia M. Ali Younis Abbosh |
| author_facet | Zhraa Zuheir Yahya Dia M. Ali Younis Abbosh |
| author_sort | Zhraa Zuheir Yahya |
| collection | DOAJ |
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The upcoming sixth-generation (6G) mobile is designed with several purposes, such as incredible improvements, ultra-fast speed, ultra-low latency, and massive connections within a small area. Bandwidth Efficiency and extensive coverage, besides sub-millisecond synchronization using a new sub-terahertz spectrum, are also considered. In order to maintain frame consistency, adapt to diverse applications, enable scalability, and minimize interferences, in 6G networks, a multi-waveform architecture is required instead of the individual waveform, which cannot meet the requirements. In this paper, a new approach to the waveform framework is presented. The proposed method integrates multi waveforms, referred to as (Waveforms Interfering). This approach combines two multicarrier schemes within a single frame, and then their performances are independently and collectively checked. The suggested approach has a Power Spectral Density (PSD) with minimal out-of-band radiation (OOBR) and a reduced guard band to 6 subcarriers between the two waveforms without causing interference. The Bit Error Rates (BER) performance compared among different orders of Quadrature Amplitude Modulation (QAM). The minimum BER achieved at 20dB SNR is 9e-7. This comparison reveals diverse performance outcomes based on the modulation orders used. The Peak Average Power Ratio (PAPR) behaves similarly to an individual scheme. This approach can effectively satisfy the strict performance requirements of 6G networks.
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| format | Article |
| id | doaj-art-b34e2bbeecbf410d9430fc16c58d1c17 |
| institution | Kabale University |
| issn | 1999-8716 2616-6909 |
| language | English |
| publishDate | 2025-06-01 |
| publisher | University of Diyala |
| record_format | Article |
| series | Diyala Journal of Engineering Sciences |
| spelling | doaj-art-b34e2bbeecbf410d9430fc16c58d1c172025-08-20T03:27:40ZengUniversity of DiyalaDiyala Journal of Engineering Sciences1999-87162616-69092025-06-0118210.24237/djes.2024.18202FBMC and UFMC Multi-Waveform Design for 6G Wireless NetworksZhraa Zuheir Yahya0Dia M. Ali1Younis Abbosh2Department of Communication Engineering, Ninevah University, Ninevah, Iraq Department of Biomedical Engineering, Ninevah University, Ninevah, Iraq Department of Biomedical Engineering, Ninevah University, Ninevah, Iraq The upcoming sixth-generation (6G) mobile is designed with several purposes, such as incredible improvements, ultra-fast speed, ultra-low latency, and massive connections within a small area. Bandwidth Efficiency and extensive coverage, besides sub-millisecond synchronization using a new sub-terahertz spectrum, are also considered. In order to maintain frame consistency, adapt to diverse applications, enable scalability, and minimize interferences, in 6G networks, a multi-waveform architecture is required instead of the individual waveform, which cannot meet the requirements. In this paper, a new approach to the waveform framework is presented. The proposed method integrates multi waveforms, referred to as (Waveforms Interfering). This approach combines two multicarrier schemes within a single frame, and then their performances are independently and collectively checked. The suggested approach has a Power Spectral Density (PSD) with minimal out-of-band radiation (OOBR) and a reduced guard band to 6 subcarriers between the two waveforms without causing interference. The Bit Error Rates (BER) performance compared among different orders of Quadrature Amplitude Modulation (QAM). The minimum BER achieved at 20dB SNR is 9e-7. This comparison reveals diverse performance outcomes based on the modulation orders used. The Peak Average Power Ratio (PAPR) behaves similarly to an individual scheme. This approach can effectively satisfy the strict performance requirements of 6G networks. https://djes.info/index.php/djes/article/view/16875G6GFBMCUFMCMulti-Waveform |
| spellingShingle | Zhraa Zuheir Yahya Dia M. Ali Younis Abbosh FBMC and UFMC Multi-Waveform Design for 6G Wireless Networks Diyala Journal of Engineering Sciences 5G 6G FBMC UFMC Multi-Waveform |
| title | FBMC and UFMC Multi-Waveform Design for 6G Wireless Networks |
| title_full | FBMC and UFMC Multi-Waveform Design for 6G Wireless Networks |
| title_fullStr | FBMC and UFMC Multi-Waveform Design for 6G Wireless Networks |
| title_full_unstemmed | FBMC and UFMC Multi-Waveform Design for 6G Wireless Networks |
| title_short | FBMC and UFMC Multi-Waveform Design for 6G Wireless Networks |
| title_sort | fbmc and ufmc multi waveform design for 6g wireless networks |
| topic | 5G 6G FBMC UFMC Multi-Waveform |
| url | https://djes.info/index.php/djes/article/view/1687 |
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