Hybrid energy harvesting-based cooperative spectrum sensing and access in heterogeneous cognitive radio networks
Hybrid energy harvesting-based cooperative spectrum sensing and access in heterogeneous cognitive radio networks
In order to design energy efficient and energy harvesting (EEH) cooperative spectrum sensing (EEH-CSS), four fundamental constraints must be considered: 1) collision constraint to protect primary users from the collision with secondary users (SUs); 2) energy-causality constraint which states that the energy harvested by a time instant must be greater than or equal to the consumed energy until that time instant; 3) energy half-duplex (EHD) constraint which prevents the batteries from charging and discharging at the same time; and 4) correlation constraint which limits the information about the primary channel (PC) state of next time slot can be extracted from the current PC state. In this regard, we consider a hybrid energy harvesting SU (EH-SU) model which can harvest energy from both renewable sources, e.g., solar and ambient radio frequency signals. A heterogeneous EEH-CSS scheme is first proposed to handle EH-SUs with nonidentical harvesting, sensing, and reporting characteristics by permitting them to sense and report at different sensing accuracy. Formulating the energy state evolution of EH-SUs with and without EHD constraint, we analyze the asymptotic activity behavior of a single EH-SU by deriving the theoretical upper bound for the chance of being active to sense and transmit. Thereafter, we develop a convex framework to find maximum achievable total throughput by optimizing the asymptotic active probability, sensing duration, and detection threshold of each SU subject to above constraints. Given a potential set of SUs, determining the optimal subset of cooperating EH-SUs is of the essence to achieve maximum achievable total throughput. Since EH-SU selection is inherently a combinatorial problem, a fast yet high performance solution is proposed based on SUs' energy harvesting, sensing, and reporting attributes. Finally, a myopic access procedure is developed to determine the active set of EH-SUs given the best subset of SUs.
correlation constraint, energy causality constraint, energy half-full duplex, myopic policy, poisson-binomial, RF energy harvesting, Wireless powered communications
37-48
Celik, Abdulkadir
f8e72266-763c-4849-b38e-2ea2f50a69d0
Alsharoa, Ahmad
7231f65e-2d21-49e0-95ac-5e3593a9ab8b
Kamal, Ahmed E.
b7e85bb0-fbc5-4dcd-80d6-011c900201dc
March 2017
Celik, Abdulkadir
f8e72266-763c-4849-b38e-2ea2f50a69d0
Alsharoa, Ahmad
7231f65e-2d21-49e0-95ac-5e3593a9ab8b
Kamal, Ahmed E.
b7e85bb0-fbc5-4dcd-80d6-011c900201dc
Celik, Abdulkadir, Alsharoa, Ahmad and Kamal, Ahmed E.
(2017)
Hybrid energy harvesting-based cooperative spectrum sensing and access in heterogeneous cognitive radio networks.
IEEE Transactions on Cognitive Communications and Networking, 3 (1), , [7817835].
(doi:10.1109/TCCN.2017.2653185).
Abstract
In order to design energy efficient and energy harvesting (EEH) cooperative spectrum sensing (EEH-CSS), four fundamental constraints must be considered: 1) collision constraint to protect primary users from the collision with secondary users (SUs); 2) energy-causality constraint which states that the energy harvested by a time instant must be greater than or equal to the consumed energy until that time instant; 3) energy half-duplex (EHD) constraint which prevents the batteries from charging and discharging at the same time; and 4) correlation constraint which limits the information about the primary channel (PC) state of next time slot can be extracted from the current PC state. In this regard, we consider a hybrid energy harvesting SU (EH-SU) model which can harvest energy from both renewable sources, e.g., solar and ambient radio frequency signals. A heterogeneous EEH-CSS scheme is first proposed to handle EH-SUs with nonidentical harvesting, sensing, and reporting characteristics by permitting them to sense and report at different sensing accuracy. Formulating the energy state evolution of EH-SUs with and without EHD constraint, we analyze the asymptotic activity behavior of a single EH-SU by deriving the theoretical upper bound for the chance of being active to sense and transmit. Thereafter, we develop a convex framework to find maximum achievable total throughput by optimizing the asymptotic active probability, sensing duration, and detection threshold of each SU subject to above constraints. Given a potential set of SUs, determining the optimal subset of cooperating EH-SUs is of the essence to achieve maximum achievable total throughput. Since EH-SU selection is inherently a combinatorial problem, a fast yet high performance solution is proposed based on SUs' energy harvesting, sensing, and reporting attributes. Finally, a myopic access procedure is developed to determine the active set of EH-SUs given the best subset of SUs.
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Published date: March 2017
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© 2017 IEEE.
Keywords:
correlation constraint, energy causality constraint, energy half-full duplex, myopic policy, poisson-binomial, RF energy harvesting, Wireless powered communications
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Local EPrints ID: 504467
URI: http://eprints.soton.ac.uk/id/eprint/504467
ISSN: 2332-7731
PURE UUID: 22028303-e465-4efc-8c03-4157582ea078
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Date deposited: 09 Sep 2025 19:58
Last modified: 13 Sep 2025 02:40
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Author:
Abdulkadir Celik
Author:
Ahmad Alsharoa
Author:
Ahmed E. Kamal
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