Abstract
We study two important aspects to make dynamic spectrum access work in practice: the admission policy of secondary users (SUs) to achieve a certain degree of quality of service and the management of the interference caused by SUs to primary users (PUs). In order to limit the forced termination probability of SUs, we evaluate the Fractional Guard Channel reservation scheme to give priority to spectrum handovers over new arrivals. We show that, contrary to what has been proposed, the throughput of SUs cannot be maximized by configuring the reservation parameter. We also study the interference caused by SUs to PUs. We propose and evaluate different mechanisms to reduce the interference, which are based on simple spectrum access algorithms for both PUs and SUs and channel repacking algorithms for SUs. Numerical results show that the reduction can be of one order of magnitude or more with respect to the random access case. Finally, we propose an adaptive admission control scheme that is able to limit simultaneously the forced termination probability of SUs and what we define as the probability of interference. Our scheme does not require any configuration parameters beyond the probability objectives. Besides, it is simple to implement and it can operate with any arrival process and distribution of the session duration.
Highlights
Cognitive radio networks are envisaged as the key technology to realize dynamic spectrum access (DSA)
We studied the effectiveness of the Fractional Guard Channel admission policy to guarantee the Quality of Service (QoS) perceived by spectrum utilization by allowing DSA users (SUs), defined in terms of their forced termination probability
We modeled the system as a continuous-time Markov chain (CTMC) which was validated by computer simulation
Summary
Cognitive radio networks are envisaged as the key technology to realize dynamic spectrum access (DSA). Blocking the request of a new SU session, even if there are enough free resources, can be employed as a strategy to reduce the number of SU sessions forcedly terminated and the interference caused to PUs. A variety of studies that focus on priority mechanisms to handle conventional handovers in cellular networks have appeared in the literature, see [8] and references therein. The proposed scheme is self-adaptive and does not require any configuration parameters beyond the targeted QoS objectives It does not rely on any particular assumptions on the traffic characteristics; that is, it can operate with any arrival process and distribution of the session duration.
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