Abstract
In cognitive radio network (CRN), secondary users (SUs) try to sense and utilize the vacant spectrum of the legitimate primary user (PU) in an efficient manner. The process of cooperation among SUs makes the sensing more authentic with minimum disturbance to the PU in achieving maximum utilization of the vacant spectrum. One problem in cooperative spectrum sensing (CSS) is the occurrence of malicious users (MUs) sending false data to the fusion center (FC). In this paper, the FC takes a global decision based on the hard binary decisions received from all SUs. Genetic algorithm (GA) using one-to-many neighbor distance along with z-score as a fitness function is used for the identification of accurate sensing information in the presence of MUs. The proposed scheme is able to avoid the effect of MUs in CSS without identification of MUs. Four types of abnormal SUs, opposite malicious user (OMU), random opposite malicious user (ROMU), always yes malicious user (AYMU), and always no malicious user (ANMU), are discussed in this paper. Simulation results show that the proposed hard fusion scheme has surpassed the existing hard fusion scheme, equal gain combination (EGC), and maximum gain combination (MGC) schemes by employing GA.
Highlights
A spectrum demand is on its rise due to new applications and wireless devices
We investigate Genetic algorithm (GA)-based cooperative spectrum sensing (CSS) to defend against sensing data falsification (SSDF) attack of malicious users (MUs) to reduce the probability of misdetection and false alarm, which results in an overall reduction in the probability of errors
Cognitive radio network parameters are set with S including normal SUs (NSUs), MUs, and fusion center (FC)
Summary
A spectrum demand is on its rise due to new applications and wireless devices. The federal communication commission (FCC) survey shows that most of the licensed radio frequency spectrum is underutilized, temporally and spatially. In comparison with [39], this work optimizes the detection, false alarm, and error results when MUs take low and high SNR of the channel in comparison with NSUs. The proposed scheme is tested at different levels of SNR and increasing number of cooperative users with simple soft decision fusion (SDF) and hard decision fusion (HDF) schemes in [28,29,30,31,32,33,34,35,36].
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