The local spectrum sensing objective in spectrum sensing is to detect the PU's signal. The sensing node's (SN) capacity to detect the PU's signal is of paramount importance. However, it is presumed to be stationary in the majority of SN in cognitive radio networks. The detection performance on local observation is significantly influenced by the mobility of the PUs and SNs. The SNs' movement generates spatial diversity in the PU's signal observation. The signal's condition would fluctuate during the sensing process as a result of Doppler effect, spatial distance, velocity, movement, and geolocation information. Therefore, a benchmark is required to compare the primary user signal detection level of stationary and moving SNs from each sensing node. The performance results have demonstrated that static nodes with SCM are superior to conventional subcarrier mapping (SCM) methods in the case of a subcarrier mapping width of α = 2. Additionally, the quantization width is uniform. It has been determined that the performance disparity is substantial, ranging from 2 dB to 4 dB. The results indicate that the static nodes SCM have achieved acceptable performance detection at a low subcarrier detection threshold (SDT) value of 0 dB up to 5 dB. Conversely, the probability of conventional SCM detection is less than 1 of probability detection (PD) value at the same low SDT value. The detection probability (PD) of static nodes with SCM is satisfactory at an SDT value of 15 dB. Moreover, the probability begins to decline until 20 dB at an SDT value of 11.5 dB, a substantial decrease that is rendered negligible. In contrast to the new subcarrier mapping (N-SCM) method, which has a false alarm probability (PFA) of approximately 0 dB to 9.5 dB, conventional subcarrier mapping (SCM) has a high false alarm probability in mobility networks. Furthermore, it is evident that the PFA curves for the conventional SCM method are lower than those of other methods at low speeds, as they approach the null value at SDT 7.5 dB. The PFA curve for both methods is higher than other velocities by attaining a null value at 10 dB, in contrast to high velocity. In general, the mobility parameter has the potential to meet the detection performance and perform well in the false alarm probability of mobile spectrum exchange. Consequently, it could be employed to provide information on spectrum exchange in the future.

Spectrum Sensing; Cooperative Sensing; Mobility Node; Spatial Diversity; Spectrum Exchange

A. Hussain, “A Hybrid and Robust Delay and Link Stability Aware (DLSA) Routing Protocol for Unmanned Aerial Ad-hoc Networks (UAANETs),” 2021.

R. Kishore, “A COMPREHENSIVE SURVEY ON RECENT ADVANCEMENTS IN COGNITIVE RADIOBASED INTERNET OF THINGS,” A COMPREHENSIVE SURVEY ON RECENT ADVANCEMENTS IN COGNITIVE RADIO-BASED INTERNET OF THINGS, p. 12.

R. Kishore, “A COMPREHENSIVE SURVEY ON RECENT ADVANCEMENTS IN COGNITIVE RADIOBASED INTERNET OF THINGS,” A COMPREHENSIVE SURVEY ON RECENT ADVANCEMENTS IN COGNITIVE RADIO-BASED INTERNET OF THINGS, p. 12.

S. Debnath, W. Arif, S. Roy, S. Baishya, and D. Sen, “A comprehensive survey of emergency communication network and management,” Wirel Pers Commun, vol. 124, no. 2, pp. 1375–1421, 2022.

M. J. N. Mahi et al., “A review on VANET research: Perspective of recent emerging technologies,” IEEE Access, vol. 10, pp. 65760–65783, 2022.

M. Ohta, T. Fujii, K. Muraoka, and M. Ariyoshi, “AN OFDM BASED SENSING INFORMATION EXCHANGE FOR COOPERATIVE SENSING IN COGNITIVE RADIO SYSTEMS,” pp. 1–5, 2008.

J. Lorincz, I. Ramljak, and D. Begušić, “A survey on the energy detection of OFDM signals with dynamic threshold adaptation: Open Issues and Future Challenges,” Sensors, vol. 21, no. 9, p. 3080, 2021.

M. Ohta, T. Fujii, K. Muraoka, and M. Ariyoshi, “A Novel Power Controlled Sensing Information Gathering for Cooperative Sensing on Shared Spectrum with Primary Spectrum,” pp. 111–115, 2011, doi: 10.4108/icst.crowncom.2011.245853.

Y. Xu, P. Cheng, Z. Chen, Y. Li, and B. Vucetic, “Mobile collaborative spectrum sensing for heterogeneous networks: A Bayesian machine learning approach,” IEEE Transactions on Signal Processing, vol. 66, no. 21, pp. 5634–5647, 2018.

E. Rodriguez-Colina, C. A. Hernandez, L. F. Pedraza, A. Prieto-Guerrero, and M. Lopez-Guerrero, “Dynamic OFDM transmission for a cognitive radio device based on a neural network and multiresolution analysis,” Wirel Commun Mob Comput, vol. 2018, 2018.

J. Lorincz, I. Ramljak, and D. Begusic, “Algorithm for evaluating energy detection spectrum sensing performance of cognitive radio MIMO-OFDM systems,” Sensors, vol. 21, no. 20, p. 6881, 2021.

M. Ohta, T. Fujii, K. Muraoka, and M. Ariyoshi, “A Novel Power Controlled Sensing Information Gathering for Cooperative Sensing on Shared Spectrum with Primary Spectrum,” pp. 111–115, 2011, doi: 10.4108/icst.crowncom.2011.245853.

M. Ohta, T. Fujii, K. Muraoka, and M. Ariyoshi, “A Cooperative Sensing Area Expansion Using Orthogonal Frequency Based Information Collection Method,” 2009.

M. Ohta, T. Fujii, K. Muraoka, and M. Ariyoshi, “A Cooperative Sensing Area Expansion Using Orthogonal Frequency Based Information Collection Method,” 2009.

A. Marwanto, S. K. S. Yusof, and M. H. Satria, “Software defined radio design for OFDM based spectrum exchange information using arduino UNO and X-Bee,” in 2017 4th International Conference on Electrical Engineering, Computer Science and Informatics (EECSI), IEEE, Sep. 2017, pp. 1–5. doi: 10.1109/EECSI.2017.8239186.

J. Tong, M. Jin, Q. Guo, and Y. Li, “Cooperative spectrum sensing: A blind and soft fusion detector,” IEEE Trans Wirel Commun, vol. 17, no. 4, pp. 2726–2737, 2018.

W. Ning, X. Huang, K. Yang, F. Wu, and S. Leng, “Reinforcement learning enabled cooperative spectrum sensing in cognitive radio networks,” Journal of Communications and Networks, vol. 22, no. 1, pp. 12–22, 2020.

A. Nasser, H. A. H. Hassan, A. Mansour, K.-C. Yao, and L. Nuaymi, “Intelligent reflecting surfaces and spectrum sensing for cognitive radio networks,” IEEE Trans Cogn Commun Netw, vol. 8, no. 3, pp. 1497–1511, 2022.

A. Nasser, H. Al Haj Hassan, J. Abou Chaaya, A. Mansour, and K.-C. Yao, “Spectrum sensing for cognitive radio: Recent advances and future challenge,” Sensors, vol. 21, no. 7, p. 2408, 2021.

G. Pan, J. Li, and F. Lin, “A cognitive radio spectrum sensing method for an OFDM signal based on deep learning and cycle spectrum,” International Journal of Digital Multimedia Broadcasting, vol. 2020, no. 1, p. 5069021, 2020.

I. F. Akyildiz, B. F. Lo, and R. Balakrishnan, “Cooperative spectrum sensing in cognitive radio networks: A survey,” Physical Communication, vol. 4, no. 1, pp. 40–62, 2011, doi: 10.1016/j.phycom.2010.12.003.

J. Wu, T. Song, Y. Yu, C. Wang, and J. Hu, “Sequential cooperative spectrum sensing in the presence of dynamic Byzantine attack for mobile networks,” PLoS One, vol. 13, no. 7, p. e0199546, 2018.

L. Sun and W. Wang, “On distribution and limits of information dissemination latency and speed in mobile cognitive radio networks,” Proceedings - IEEE INFOCOM, pp. 246–250, 2011, doi: 10.1109/INFCOM.2011.5935069.

R. Liu and E. Zheng, “Research on the Intelligent Signal Channel Sensing Based ICI Elimination Algorithm of the OFDM System,” Mobile Networks and Applications, Dec. 2016, doi: 10.1007/s11036-016-0792-7.

W.-Y. Lee and I. F. Akyildiz, “Spectrum-aware mobility management in cognitive radio cellular networks,” IEEE Trans Mob Comput, vol. 11, no. 4, pp. 529–542, 2012.

W.-Y. Lee and I. F. Akyildiz, “Spectrum-aware mobility management in cognitive radio cellular networks,” IEEE Trans Mob Comput, vol. 11, no. 4, pp. 529–542, 2012.

A. Goldsmith, Wireless communications. Cambridge university press, 2005.

F. Xiong and M. Andro, “The Effect of Doppler Frequency Shift, Frequency Offset of the Local Oscillators, and Phase Noise on the Performance of Coherent OFDM Receivers,” 2001.

H. Uchiyama et al., “Study on soft decision based cooperative sensing for cognitive radio networks,” IEICE transactions on communications, vol. 91, no. 1, pp. 95–101, 2008.

H. Uchiyama et al., “Study on Cooperative Sensing in Cognitive Radio based AD-HOC Network,” 2007 IEEE 18th International Symposium on Personal, Indoor and Mobile Radio Communications, pp. 1–5, 2007, doi: 10.1109/PIMRC.2007.4394622.

T. Balachander, K. Ramana, R. M. Mohana, G. Srivastava, and T. R. Gadekallu, “Cooperative spectrum sensing deployment for cognitive radio networks for internet of things 5G wireless communication,” Tsinghua Sci Technol, vol. 29, no. 3, pp. 698–720, 2023.

R. Awathankar, G. Phade, O. Vaidya, M. Gade, and B. Kakde, “Theoretical approach on spectrum optimization in telecommunication network using artificial intelligence,” in AIP Conference Proceedings, AIP Publishing, 2024.

X. Cao et al., “AI-empowered multiple access for 6G: A survey of spectrum sensing, protocol designs, and optimizations,” Proceedings of the IEEE, 2024.

R. Ahmed, Y. Chen, B. Hassan, L. Du, T. Hassan, and J. Dias, “Hybrid machine-learning-based spectrum sensing and allocation with adaptive congestion-aware modeling in CR-assisted IoV networks,” IEEE Internet Things J, vol. 9, no. 24, pp. 25100–25116, 2022.

R. KoteswaraRao and C. Sharanya, “An Effective Hybrid Spectrum Sensing Methodology in Cognitive Radio Network Using Deep Temporal Convolution Network,” in 2023 4th International Conference on Smart Electronics and Communication (ICOSEC), IEEE, 2023, pp. 1478–1484.

H. He and H. Jiang, “Deep learning based energy efficiency optimization for distributed cooperative spectrum sensing,” IEEE Wirel Commun, vol. 26, no. 3, pp. 32–39, 2019.

S. B. Goyal, P. Bedi, J. Kumar, and V. Varadarajan, “Deep learning application for sensing available spectrum for cognitive radio: An ECRNN approach,” Peer Peer Netw Appl, vol. 14, no. 5, pp. 3235–3249, 2021.

B. Salehi et al., “Deep learning on multimodal sensor data at the wireless edge for vehicular network,” IEEE Trans Veh Technol, vol. 71, no. 7, pp. 7639–7655, 2022.

H. Chen, Z. Wang, and L. Zhang, “Collaborative spectrum sensing for illegal drone detection: A deep learningbased image classification perspective,” China Communications, vol. 17, no. 2, pp. 81–92, 2020.

O. P. Awe, D. A. Babatunde, S. Lambotharan, and B. AsSadhan, “Second order Kalman filtering channel estimation and machine learning methods for spectrum sensing in cognitive radio networks,” Wireless Networks, vol. 27, no. 5, pp. 3273–3286, 2021.

M. R. Amin et al., “Unscented kalman filter based on spectrum sensing in a cognitive radio network using an adaptive fuzzy system,” Big Data and Cognitive Computing, vol. 2, no. 4, p. 39, 2018.

K. Tekbıyık, G. K. Kurt, and A. Lesage-Landry, “Federated Learning for UAV-Based Spectrum Sensing: Enhancing Accuracy Through SNR-Weighted Model Aggregation,” arXiv preprint arXiv:2411.11159, 2024.

Z. Chen, Y.-Q. Xu, H. Wang, and D. Guo, “Federated learning-based cooperative spectrum sensing in cognitive radio,” IEEE Communications Letters, vol. 26, no. 2, pp. 330–334, 2021.

M. Wasilewska, H. Bogucka, and A. Kliks, “Federated learning for 5G radio spectrum sensing,” Sensors, vol. 22, no. 1, p. 198, 2021.

H. Mathur and T. Deepa, “A novel precoded digitized OFDM based NOMA system for future wireless communication,” Optik (Stuttg), vol. 259, p. 168948, 2022.

M. Parvathy, “Reduction of BER and PAPR for Fourier Transform based in downlink NOMA-OFDM,” in 2022 3rd International conference on electronics and sustainable communication systems (ICESC), IEEE, 2022, pp. 181–185.