Enhanced Energy Detection for Multi-band Spectrum Sensing under RF Imperfections

In this paper, we study simultaneous multiband or multichannel spectrum sensing in cognitive radio context. The sensing receiver RF front-end is assumed to deploy wideband multichannel IQ downconversion which is prone to several RF impairments, such as IQ imbalance. Assuming that the individual channel sensing is building on energy detection, we first analyze the spectrum sensing performance of the multichannel sensing receiver in terms of false alarm and detection probabilities. The analysis shows that IQ imbalance is especially harmful in terms of false alarms, and is greatly emphasized when the overall downconverted signal has high dynamic range. Motivated by this, we present an efficient digital compensation scheme, called energy correction method, where the sensing statistics of any particular channel are properly adjusted based on the corresponding mirror-channel statistics such that the effect of the crosstalk is minimized. Optimum minimum mean-squared error (MMSE) solution for the energy correction processing is first derived, complemented then with a practical low-complexity sample estimator. Extensive computer simulations demonstrate that under various parameter settings for IQ imbalance and receiver dynamic range, the proposed scheme yields sensing performance practically identical to the IQ imbalance free reference performance. This offers feasible RF impairment -aware energy detection solution for practical multichannel sensing receivers.