Optimal linear weighted cooperative spectrum sensing for clustered-based cognitive radio networks

被引:0
作者
Haiyan Ye
Jiabao Jiang
机构
[1] Chaohu University,College of Information Engineering
来源
EURASIP Journal on Wireless Communications and Networking | / 2021卷
关键词
Linear weighted fusion; Cooperative spectrum sensing; Signal-to-noise ratio; Cognitive radio networks; Fusion center;
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摘要
The lack of spectrum resources restricts the development of wireless communication applications. In order to solve the problems of low spectrum utilization and channel congestion caused by the static division of spectrum resource, this paper proposes an optimal linear weighted cooperative spectrum sensing for clustered-based cognitive radio networks. In this scheme, different weight values will be assigned for cooperative nodes according to the SNR of cognitive users and the historical sensing accuracy. In addition, the cognitive users can be clustered, and the users with the better channel characteristics will be selected as cluster heads for gathering the local sensing information. Simulation results show that the proposed scheme can obtain better sensing performance, improve the detection probability and reduce the error probability.
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  • [11] Garrigues C(2018)A quantization-based multi-bit data fusion scheme for cooperative spectrum sensing in cognitive radio networks Sensors 18 473-486
  • [12] Zikria Y(2016)Joint selection for cooperative spectrum sensing in wireless sensor networks IEEE Sens. J. 16 7837-7838
  • [13] Ishmanov F(2013)Spatial-temporal opportunity detection for spectrum-heterogeneous cognitive radio networks: two-dimensional sensing IEEE Trans. Wirel. Commun. 12 516-526
  • [14] Afzal M(2020)Mobile internet of things under data physical fusion technology IEEE Internet Things J. 7 4616-4624
  • [15] Kim S(2021)Efficient spike-driven learning with dendritic event-based processing Front. Neurosci. 70 1-12
  • [16] Nam S(2020)Icing-EdgeNet: a pruning lightweight edge intelligent method of discriminative driving channel for ice thickness of transmission lines IEEE Trans. Instrum. Meas. 7 7622-7654
  • [17] Yu H(2017)High-resolution transport-of-intensity quantitative phase microscopy with annular illumination Sci. Rep. 14 118-129
  • [18] Chen Y(2020)video coding optimization for virtual reality 360-degree source IEEE J. Sel. Top. Signal Process. 7 5706-5712
  • [19] Oh H(2020)Interaction of edge-cloud computing based on SDN and NFV for next generation IoT IEEE Internet Things J. 9 1115-1119
  • [20] Leonard MR(2020)Efficient deployment with geometric analysis for mmWave UAV communications IEEE Wirel. Commun. Lett. 24 6062-6071
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