In a cognitive radio setting, this thesis studies transmit power allocation as well as local thresholds allocation for secondary users (SUs) with the aim of maximizing the global probability of detection at the fusion center (FC). This work considers hard decision (HD) based cooperative sensing (CS). Based on the received observations on the listening channel, each SU uses likelihood ratio test (LRT) to generate a binary decision and then sends to the FC over error-prone reporting channel. We assume the reporting channels are independent and identically distributed (i.i.d.) Rayleigh fading channels and the FC employs the majority rule to make a final decision. The exact formulae of the global probability of detection and global probability of false alarm at the FC are derived. Furthermore, when the reporting channels are in high SNR regime, we derived the analytic and approximate formulae of the global probability of detection and the global probability of false alarm at the FC. To improve detection performance in our system model, we formulate an optimization problem which could be described as follows: maximize the global probability of detection at the FC while satisfying global probability of false alarm and transmit power constraints. When comparing global probability of detection under uniform transmit power allocation with non-uniform transmit power allocation, simulation results show that improved detection performance at the FC is achieved.