Abstract
In this paper, we propose an innovative self‐organizing medium access control mechanism for a distributed cognitive radio network (CRN) in which utilization is maximized by minimizing the collisions and missed opportunities. This is achieved by organizing the users of the CRN in a queue through a timer and user ID and providing channel access in an orderly fashion. To efficiently organize the users in a distributed, ad hoc network with less overhead, we reduce the sensing period through parallel sensing wherein the users are divided into different groups and each group is assigned a different portion of the primary spectrum band. This consequently augments the number of discovered spectrum holes which then are maximally utilized through the self‐organizing access scheme. The combination of two schemes augments the effective utilization of primary holes to above 95%, even in impasse situations due to heavy primary network loading, thereby achieving higher network throughput than that achieved when each of the two approaches are used in isolation. By efficiently combining parallel sensing with the self‐organizing MAC (PSO‐MAC), a synergy has been achieved that affords the gains which are more than the sum of the gains achieved through each one of these techniques individually. In an experimental scenario with 50% primary load, the network throughput achieved with combined parallel sensing and self‐organizing MAC is 50% higher compared to that of parallel sensing and 37% better than that of self‐organizing MAC. These results clearly demonstrate the efficacy of the combined approach in achieving optimum performance in a CRN.
Highlights
The demand for spectrum has grown exponentially over the last two decades due to unprecedented growth and proliferation of wireless devices, systems, and services
We analyze the performances of parallel sensing with the self-organizing MAC (PSO-MAC), parallel sensing-random access MAC (PRA-MAC), and RSOMAC protocols for the considered system model and compare the results in terms of the discovered idle channels, idle channel utilization, and the network throughput
To minimize this overhead and to maximize the useful time in a transmission cycle, an enhanced frame structure has been designed that unifies these two mechanisms while keeping the overhead to a minimum. This improved frame structure enables to achieve the synergy where the gain of this unified approach is more than the sum of the gains of the two schemes working in isolation
Summary
The demand for spectrum has grown exponentially over the last two decades due to unprecedented growth and proliferation of wireless devices, systems, and services. Combining the two goals penalize one another due to excessive overhead, in the ad hoc CRNs employing common control channel for coordination among the SUs. The goal is to provide a unified common control channel frame structure that facilitates to improve the utilization, maximize the hole discoveries, and extend the transmission time in a transmission cycle and adjusts dynamically to the varying network conditions. (1) A unified frame structure for CRN MAC has been proposed that combines parallel sensing with the organized medium access to improve the utilization and maximize the hole discoveries (2) The proposed PSO-MAC has been carefully designed to keep the overhead of the frame structure of the common control channel to a minimum so that the transmission time in a transmission cycle is extended and a synergic effect is achieved.
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