A discrete-time multi-server queueing model for opportunistic spectrum access systems

Abstract

In opportunistic spectrum access communication systems, secondary users (SUs) exploit the spectrum holes not used by the primary users (PUs) and cease their transmissions whenever primary users reuse their spectrum bands. To study the mean time an SU spends in the system we propose a discrete-time multi-server access model. Since periodic sensing is commonly used to protect the PU, discrete-time models are more convenient to analyze the performance of the SU system. Additionally, a multi-server access model is assumed in order to give the SU the capability to access a channel that is not occupied by a PU or any other SUs. We derive the probability generating function of the number of connections in the system. Then we derive a formula for the mean response time of an SU. In the numerical results we show the relationship between the mean response time and the SU traffic intensity. In addition, we show the effect of changing the number of channels in the system and the PU traffic intensity on the mean response time of an SU. Finally, simulation results are shown to validate the proposed theoretical model and reveal that the numerical results fit the simulated results well.