Cooperative Delay-Constrained Cognitive Radio Networks: Delay-Throughput Trade-Off With Relaying Full-Duplex Capability

Ali, Ali Gaber Mohamed; Youssef, El-Sayed A.; Rizk, Mohamed R. M.; Salman, Mohamed; Seddik, Karim G.

doi:10.1109/access.2020.2964565

Cited by 4 publications

(1 citation statement)

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“…The network random traffic was modeled using a discrete time queueing system where time is segmented into slots with packet arrival and departure assumed to take place in each time slot. Similarly, queue performance of CRN was studied in [20], while SU throughput in the presence of PU QoS requirement was maximized in [21].…”

Section: A Related Workmentioning

confidence: 99%

Spatiotemporal Characterization of Users’ Experience in Massive Cognitive Radio Networks

2020

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The need to capture the actual network traffic condition and fundamental queueing dynamics in a massive cognitive radio network (CRN) is important for proper analysis of the intrinsic effects of spatial distribution while capturing the essential temporal distribution properties of the network. In massive CRN, many users, including primary and secondary users, transmit on scarce spectrum resources. While primary users (PUs) are delay-sensitive users that require prioritized access over secondary users (SUs), carrying out analysis that captures this property becomes imperative if users' service experience is to be satisfactory. This paper presents priority conscious spatiotemporal analysis capable of characterizing users' experience in massive CRN. Users in the primary priority queue were considered to have pre-emptive priory over users in the virtual and secondary priority queues. A Geo/G/1 discrete-time Markov chain queueing system was adopted to characterize both primary and secondary priority queues, while the virtual priority queue was analyzed as part of the secondary priority queue. Using the tools of stochastic geometry and queueing theory, the user's coverage probability was determined while the delay experienced by each class of users in the network was obtained using existing results. Through the obtained delay for each class of users in the network, the corresponding quality of service was also obtained. The results obtained show that the proposed framework is capable of accurately characterizing users' service experience in massive CRN.

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Section: A Related Workmentioning

confidence: 99%