Efficient Switched-Beam Detection for Dynamic Spectrum Sharing in 6G Wireless Networks With Full Duplex Technology at the THz Band
The demand for higher data rates and bandwidth-intensive applications in the digital age is driving the need for cutting-edge technologies in future 6G systems, such as terahertz (THz) and full duplex (FD) communications. These technologies promise exceptional performance enhancement when combined w...
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2025-01-01
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| author | Andrea Tani Dania Marabissi |
| author_facet | Andrea Tani Dania Marabissi |
| author_sort | Andrea Tani |
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| description | The demand for higher data rates and bandwidth-intensive applications in the digital age is driving the need for cutting-edge technologies in future 6G systems, such as terahertz (THz) and full duplex (FD) communications. These technologies promise exceptional performance enhancement when combined with a dynamic spectrum management approach based on Cognitive Radio (CR). This paper explores spectrum sensing (SS) methods that do not require any prior information suitable for FD-THz communications, addressing challenges posed by residual self-interference (RSI) and molecular noise, which characterize THz communications. Both molecular re-radiation and RSI are sources of colored noise that dominate additive white Gaussian noise, complicating the operations of SS algorithms that do not require prior information based on the eigenvalues of the sample covariance matrix. To address this issue, we propose a low-complexity solution using a switched beam technique, along with a whitening matrix derived from a dataset containing RSI, molecular noise, and two largest eigenvalue (LE) detectors. The LE detector is introduced as an upper bound applicable only when perfect knowledge of the variances of all the noise components is available, which is unlikely in most practical scenarios. Therefore, we propose a novel, low-complexity detector not relying on prior information, based on scaled LE (SLE), which estimates the molecular noise and the AWGN variance online. The algorithm also includes a heuristic to adjust the contribution of the RSI and molecular noise components, ensuring that the detector retains an approximately constant false alarm rate (CFAR) property under typical operating conditions. Numerical simulations show that the proposed SS method is feasible and robust. Compared to the recursive least squares (RLS) adaptive filtering benchmark, it offers a more robust false alarm probability, particularly in the low-AWGN regime, with detection performance similar to or slightly lower than the RLS detector, but with significantly lower computational complexity. |
| format | Article |
| id | doaj-art-1d6f7599c69744bc814625417b0cd2d3 |
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| issn | 2169-3536 |
| language | English |
| publishDate | 2025-01-01 |
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| spelling | doaj-art-1d6f7599c69744bc814625417b0cd2d32025-08-20T01:54:34ZengIEEEIEEE Access2169-35362025-01-0113576625767510.1109/ACCESS.2025.355460610938550Efficient Switched-Beam Detection for Dynamic Spectrum Sharing in 6G Wireless Networks With Full Duplex Technology at the THz BandAndrea Tani0https://orcid.org/0000-0002-8414-1403Dania Marabissi1https://orcid.org/0000-0002-7075-3556Department of Information Engineering, University of Florence, Florence, ItalyDepartment of Information Engineering, University of Florence, Florence, ItalyThe demand for higher data rates and bandwidth-intensive applications in the digital age is driving the need for cutting-edge technologies in future 6G systems, such as terahertz (THz) and full duplex (FD) communications. These technologies promise exceptional performance enhancement when combined with a dynamic spectrum management approach based on Cognitive Radio (CR). This paper explores spectrum sensing (SS) methods that do not require any prior information suitable for FD-THz communications, addressing challenges posed by residual self-interference (RSI) and molecular noise, which characterize THz communications. Both molecular re-radiation and RSI are sources of colored noise that dominate additive white Gaussian noise, complicating the operations of SS algorithms that do not require prior information based on the eigenvalues of the sample covariance matrix. To address this issue, we propose a low-complexity solution using a switched beam technique, along with a whitening matrix derived from a dataset containing RSI, molecular noise, and two largest eigenvalue (LE) detectors. The LE detector is introduced as an upper bound applicable only when perfect knowledge of the variances of all the noise components is available, which is unlikely in most practical scenarios. Therefore, we propose a novel, low-complexity detector not relying on prior information, based on scaled LE (SLE), which estimates the molecular noise and the AWGN variance online. The algorithm also includes a heuristic to adjust the contribution of the RSI and molecular noise components, ensuring that the detector retains an approximately constant false alarm rate (CFAR) property under typical operating conditions. Numerical simulations show that the proposed SS method is feasible and robust. Compared to the recursive least squares (RLS) adaptive filtering benchmark, it offers a more robust false alarm probability, particularly in the low-AWGN regime, with detection performance similar to or slightly lower than the RLS detector, but with significantly lower computational complexity.https://ieeexplore.ieee.org/document/10938550/Cognitive radiospectrum sensingfull duplexmolecular noiseterahertz |
| spellingShingle | Andrea Tani Dania Marabissi Efficient Switched-Beam Detection for Dynamic Spectrum Sharing in 6G Wireless Networks With Full Duplex Technology at the THz Band IEEE Access Cognitive radio spectrum sensing full duplex molecular noise terahertz |
| title | Efficient Switched-Beam Detection for Dynamic Spectrum Sharing in 6G Wireless Networks With Full Duplex Technology at the THz Band |
| title_full | Efficient Switched-Beam Detection for Dynamic Spectrum Sharing in 6G Wireless Networks With Full Duplex Technology at the THz Band |
| title_fullStr | Efficient Switched-Beam Detection for Dynamic Spectrum Sharing in 6G Wireless Networks With Full Duplex Technology at the THz Band |
| title_full_unstemmed | Efficient Switched-Beam Detection for Dynamic Spectrum Sharing in 6G Wireless Networks With Full Duplex Technology at the THz Band |
| title_short | Efficient Switched-Beam Detection for Dynamic Spectrum Sharing in 6G Wireless Networks With Full Duplex Technology at the THz Band |
| title_sort | efficient switched beam detection for dynamic spectrum sharing in 6g wireless networks with full duplex technology at the thz band |
| topic | Cognitive radio spectrum sensing full duplex molecular noise terahertz |
| url | https://ieeexplore.ieee.org/document/10938550/ |
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