Title :
A new adaptive functional-link neural-network-based DFE for overcoming co-channel interference
Author :
Hussain, Amir ; Soraghan, John J. ; Durrani, Tariq S.
Author_Institution :
Signal Process. Div., Strathclyde Univ., Glasgow, UK
fDate :
11/1/1997 12:00:00 AM
Abstract :
A new approach for the decision feedback equalizer (DFE) based on the functional-link neural network is described. The structure is applied to the problem of adaptive equalization in the presence of intersymbol interference (ISI), additive white Gaussian noise, and co-channel interference (CCI). It is shown through simulation results for a severe amplitude distorted co-channel system that the decision feedback functional-link equalizer (DFFLE) provides significantly superior bit-error rate (BER) performance characteristics compared to the conventional DFE, the linear transversal equalizer (LTE), the nonlinear radial basis function (RBF) neural-network-based structures and the feed-forward functional-link equalizer (FFLE)-based structures. The DFFLE is also shown to have a significantly simpler computational requirement relative to the RBF and the FFLE
Keywords :
Gaussian noise; adaptive equalisers; cochannel interference; coding errors; decision feedback equalisers; error statistics; interference suppression; intersymbol interference; learning (artificial intelligence); recurrent neural nets; telecommunication computing; white noise; BER performance; ISI; adaptive DFE; adaptive equalization; additive white Gaussian noise; amplitude distorted cochannel system; bit error rate; cochannel interference; decision feedback equalizer; decision feedback functional-link equalizer; feedforward functional-link equalizer; functional-link neural network; intersymbol interference; learning algorithm; linear transversal equalizer; nonlinear radial basis function; simulation results; Adaptive equalizers; Additive white noise; Bit error rate; Decision feedback equalizers; Interchannel interference; Intersymbol interference; Neural networks; Neurofeedback; Nonlinear distortion; Radiofrequency interference;
Journal_Title :
Communications, IEEE Transactions on
