Title :
A hybrid adaptive blind equalization algorithm for QAM signals in wireless communications
Author :
He, Lin ; Amin, Moeness G. ; Reed, Charles, Jr. ; Malkemes, Robert C.
Author_Institution :
Center for Adv. Commun., Villanova Univ., PA, USA
fDate :
7/1/2004 12:00:00 AM
Abstract :
A hybrid adaptive channel equalization technique for quadrature amplitude modulation (QAM) signals is proposed. The proposed algorithm, which is referred to as the modified constant modulus algorithm (MCMA), minimizes an error cost function that includes both amplitude and phase of the equalizer output. In addition to the amplitude-dependent term that is provided by the conventional constant modulus algorithm (CMA), the cost function includes an additive signal constellation matched error (CME) term. This term can be designed to satisfy a set of desirable properties. The MCMA is compared with the CMA for blind equalization. The performance is measured for wireless channels using both transient and steady-state behavior of the mean square error (MSE). It is shown that MCMA is superior and more robust in low signal-to-noise ratio (SNR) environments. Simulation results demonstrate that using MCMA improves adaptive channel equalization by increasing the convergence rate and decreasing the steady-state mean square error.
Keywords :
adaptive equalisers; blind equalisers; convergence of numerical methods; indoor radio; mean square error methods; quadrature amplitude modulation; MSE; QAM signals; SNR; adaptive channel equalization; additive signal constellation matched error; convergence rate; error cost function minimization; hybrid adaptive channel equalization technique; indoor wireless communications; modified constant modulus algorithm; quadrature amplitude modulation; signal-to-noise ratio; steady-state mean square error; transient mean square error; wireless channels; Adaptive equalizers; Additives; Blind equalizers; Constellation diagram; Cost function; Mean square error methods; Quadrature amplitude modulation; Robustness; Steady-state; Wireless communication;
Journal_Title :
Signal Processing, IEEE Transactions on
DOI :
10.1109/TSP.2004.828913
