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Decode and forward relaying for energy-efficient multiuser cooperative cognitive radio network with outage constraints
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Decode and forward relaying for energy-efficient multiuser cooperative cognitive radio network with outage constraints
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Journal Article
Decode and forward relaying for energy-efficient multiuser cooperative cognitive radio network with outage constraints
2014
Overview
We investigate the optimal allocation of power in the downlink cooperative cognitive radio network using decode and forward (DF) relaying technique. The power allocation in DF relaying for green cooperative cognitive radio with an objective of maximising energy-efficiency is a constraint non-linear non-convex fractional programming problem. The optimisation needs to satisfy the primary users interference constraints and secondary users outage constraints. The authors present the optimal power allocation in DF relaying by transforming the constraint non-linear non-convex fractional power allocation problem into a concave fractional programme by using Charnes–Cooper transformation. The authors also present an iterative algorithm that uses parametric transformation and guarantees ε-optimal convergence. The convergence of the iterative algorithm is proved and numerical results obtained for cooperative cognitive radio network are presented with different network parameter settings.
Publisher
The Institution of Engineering and Technology,John Wiley & Sons, Inc
Subject
/ Charnes‐Cooper transformation
/ concave fractional programme
/ decode and forward communication
/ downlink cooperative cognitive radio network
/ energy efficient multiuser cooperative cognitive radio network
/ Networks
/ nonlinear non convex fractional programming problem
/ relay networks (telecommunication)
/ Relaying
