Abstract
The exact and simple distributions of finite random matrix theory (FRMT) are critically important for cognitive radio networks (CRNs). In this paper, we unify some existing distributions of the FRMT with the proposed coefficient matrices (vectors) and represent the distributions with the coefficient-based formulations. A coefficient reuse mechanism is studied, i.e., the same coefficient matrices (vectors) can be exploited to formulate different distributions. For instance, the same coefficient matrices can be used by the largest eigenvalue (LE) and the scaled largest eigenvalue (SLE); the same coefficient vectors can be used by the smallest eigenvalue (SE) and the Demmel condition number (DCN). A new and simple cumulative distribution function (CDF) of the DCN is also deduced. In particular, the dimension boundary between the infinite random matrix theory (IRMT) and the FRMT is initially defined. The dimension boundary provides a theoretical way to divide random matrices into infinite random matrices and finite random matrices. The FRMT-based spectrum sensing (SS) schemes are studied for CRNs. The SLE-based scheme can be considered as an asymptotically-optimal SS scheme when the dimension K is larger than two. Moreover, the standard condition number (SCN)-based scheme achieves the same sensing performance as the SLE-based scheme for dual covariance matrix . The simulation results verify that the coefficient-based distributions can fit the empirical results very well, and the FRMT-based schemes outperform the IRMT-based schemes and the conventional SS schemes.
Highlights
Cognitive radio networks (CRNs), working as a sharp tool to deal with the spectrum scarcity problem, have been recognized as one of the most promising communication technologies in recent years [1,2,3]
The sensing performances of the finite random matrix theory (RMT) (FRMT)-based scheme, the infinite RMT (IRMT)-based scheme and the conventional cooperative SS scheme are shown in Figure 8, in which the number of the sensors is K = 3, and the sample number per sensor is N = 6
The coefficient-based distributions of the FRMT have been discussed in this paper
Summary
Cognitive radio networks (CRNs), working as a sharp tool to deal with the spectrum scarcity problem, have been recognized as one of the most promising communication technologies in recent years [1,2,3]. As the key function of CRNs, spectrum sensing (SS) is used to check the accessibility of the target frequency bands, which belong to the primary user (PU) systems, but are not occupied [4,5]. The random matrix theory (RMT) has been used in wireless communication systems [6,7,8,9,10,11]. According to the size of matrix dimensions, the RMT can generally be divided into two types: infinite RMT (IRMT) with large dimensions and finite RMT (FRMT) with finite dimensions. The distributions of the eigenvalues and Sensors 2016, 16, 1183; doi:10.3390/s16081183 www.mdpi.com/journal/sensors
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