Abstract
With the development of wireless communication technology, cognitive radio needs to solve the spectrum sensing problem of wideband wireless signals. Due to performance limitation of electronic components, it is difficult to complete spectrum sensing of wideband wireless signals at once. Therefore, it is required that the wideband wireless signal has to be split into a set of sub-bands before the further signal processing. However, the sequence of sub-band perception has become one of the important factors, which deeply-impact wideband spectrum sensing performance. In this paper, we develop a novel approach for sub-band selection through the non-stationary multi-arm bandit (NS-MAB) model. This approach is based on a well-known order optimal policy for NS-MAB mode called discounted upper confidence bound (D-UCB) policy. In this paper, according to different application requirements, various discount functions and exploration bonuses of D-UCB are designed, which are taken as the parameters of the policy proposed in this paper. Our simulation result demonstrates that the proposed policy can provide lower cumulative regret than other existing state-of-the-art policies for sub-band selection of wideband spectrum sensing.
Highlights
With the rapid development of internet of things and 5G technologies, wireless spectrum resources are becoming scarcer
The research on traditional wideband spectrum sensing architecture is still meaningful: Segment the wideband spectrum into a set of sub-bands according to the requirement of users, and conduct spectrum sensing for a certain sub-band at each time slot [7]
O-Discounted upper confidence bound (D-UCB) policy and windowed recency-based exploration (WRBE) policy can reach more than 90%, and the non-stationary recency-based exploration (NRBE) policy can maintained near 85%, the D-UCB policy is maintained at around 75%, and the sliding window UCB (SW-UCB) policy is slightly higher than 50%, EXP3.S is lowest, it only reached 20%
Summary
With the rapid development of internet of things and 5G technologies, wireless spectrum resources are becoming scarcer. As a promising solution for efficient radio spectrum utilization [1,2], meets many challenges, especially spectrum sensing technology [3], wideband spectrum sensing is one of challenges. Various solutions have been proposed on wideband spectrum sensing, such as the single-channel sub-Nyquist sampling algorithm [4] and compressed sensing [5]. Compressed sensing is the most promising method, it is still difficult to solve the spectrum sensing problem for wideband wireless signals when faced with noncontiguous bands, complex, and changeable electromagnetic environment [6]. In the case of fixed spectrum sensing algorithm, how to determine the sensing sequence of sub-bands is the main research content to improve the sensing ability of cognitive radio
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