par Renard, Julien 
;Verlant-Chenet, Jonathan ;Dricot, Jean-Michel ;De Doncker, Philippe ;Horlin, François
Référence EURASIP Journal on wireless communications and networking, 2010, 721695
Publication Publié, 2010-07
;Verlant-Chenet, Jonathan ;Dricot, Jean-Michel ;De Doncker, Philippe ;Horlin, François Référence EURASIP Journal on wireless communications and networking, 2010, 721695
Publication Publié, 2010-07
Article révisé par les pairs
| Résumé : | Recent years have shown a growing interest in the concept of Cognitive Radios (CRs), able to access portions of the electromagnetic spectrum in an opportunistic operating way. Such systems require efficient detectors able to work in low Signal-to-Noise Ratio (SNR) environments, with little or no information about the signals they are trying to detect. Energy detectors are widely used to perform such blind detection tasks, but quickly reach the so-called SNR wall below which detection becomes impossible Tandra (2005). Cyclostationarity detectors are an interesting alternative to energy detectors, as they exploit hidden periodicities present in man-made signals, but absent in noise. Such detectors use quadratic transformations of the signals to extract the hidden sine-waves. While most of the literature focuses on the second-order transformations of the signals, we investigate the potential of higher-order transformations of the signals. Using the theory of Higher-Order Cyclostationarity (HOCS), we derive a fourth-order detector that performs similarly to the second-order ones to detect linearly modulated signals, at SNR around 0 dB, which may be used if the signals of interest do not exhibit second-order cyclostationarity. More generally this paper reviews the relevant aspects of the cyclostationary and HOCS theory, and shows their potential for spectrum sensing. Copyright © 2010 Julien Renard et al. |
