Title :
Cross-Layer Optimization and Receiver Localization for Cognitive Networks Using Interference Tweets
Author :
Marques, Antonio G. ; Dall´Anese, Emiliano ; Giannakis, Georgios
Author_Institution :
Dept. of Signal Theor. & Commun., Univ. Rey Juan Carlos, Fuenlabrada, Spain
Abstract :
A cross-layer resource allocation scheme for underlay multi-hop cognitive radio networks is formulated, in the presence of uncertain propagation gains and locations of primary users (PUs). Secondary network design variables are optimized under long-term probability-of-interference constraints, by exploiting channel statistics and maps that pinpoint areas where PU receivers are likely to reside. These maps are tracked using a Bayesian approach, based on 1-bit messages - here refereed to as "interference tweet" - broadcasted by the PU system whenever a communication disruption occurs due to interference. Although nonconvex, the problem has zero duality gap, and it is optimally solved using a Lagrangian dual approach. Numerical experiments demonstrate the ability of the proposed scheme to localize PU receivers, as well as the performance gains enabled by this minimal primary-secondary interplay.
Keywords :
cognitive radio; concave programming; radio receivers; radiofrequency interference; resource allocation; Bayesian approach; Lagrangian dual approach; PU system; channel statistics; cross-layer optimization; cross-layer resource allocation; interference tweets; nonconvex problem; primary user locations; primary-secondary interplay; probability-of-interference constraints; receiver localization; secondary network design variables; uncertain propagation gains; underlay multihop cognitive radio networks; zero duality gap; Fading; Interference; Optimization; Receivers; Sensors; Uncertainty; Wireless communication; Bayesian estimation; Cognitive radio networks; Lagrange dual; cross-layer optimization; receiver localization;
Journal_Title :
Selected Areas in Communications, IEEE Journal on
DOI :
10.1109/JSAC.2014.1403009
