Abstract
We propose a robust beamforming design for underlay cognitive radio networks where multiple secondary transmitters communicate with corresponding secondary receivers and coexist with a primary network. We consider a scenario where all transmitters have multiple antennas and all primary and secondary receivers are equipped with a single antenna. The main focus is to design the optimal transmit beamforming vectors for secondary transmitters that maximize the minimum of the received signal-to-interference-plus-noise ratios of the cognitive users. The interference powers to the primary receivers are kept below a threshold to guarantee that the performance of the primary network does not degrade due to the secondary network. Imperfect channel state information (CSI) in all relevant channels are considered, and a bounded ellipsoidal uncertainty model is used to model the CSI errors. We recast the problem in the form of semidefinite program and an iterative algorithm based on the bisection method is proposed to achieve the optimal solution. Further, we propose upper and lower bounds for the optimal value of the considered problem, which provides better initialization for the algorithm. Numerical simulations are conducted to show the effectiveness of the proposed method against the non-robust design.
Highlights
Scarcity of wireless spectrum is one of the major challenges faced by the modern wireless communication industry
We address the problem of maximizing the worst signal-to-interference-plus-noise ratio (SINR) of any secondary user subject to interference constraints to primary network and individual power constraints
We have considered that the network controller has imperfect channel state information (CSI) knowledge in all relevant channels, and bounded ellipsoidal uncertainty model has been used to model the CSI errors
Summary
Scarcity of wireless spectrum is one of the major challenges faced by the modern wireless communication industry. Due to rapid deployment of wireless services in the recent past and the fixed spectrum allocation policy, the wireless spectrum has been increasingly crowded. On the other hand, according to the Federal Communication Commissions and other regulatory bodies, most of the allocated spectrum is under utilized [1]. The secondary usage of wireless spectrum has been proposed as a method to utilize more efficiently the wireless spectrum [1,2,3,4]. Cognitive radio networks (CRNs) [2,3,4] operate on this idea of the secondary usage of spectrum. The secondary network is allowed to opportunistically access the spectrum owned by the primary network provided that
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