Title :
Decision feedback recurrent neural equalization with fast convergence rate
Author :
Choi, Jongsoo ; Bouchard, Martin ; Yeap, Tet Hin
Author_Institution :
Sch. of Inf. Technol. & Eng., Univ. of Ottawa, Ont., Canada
fDate :
5/1/2005 12:00:00 AM
Abstract :
Real-time recurrent learning (RTRL), commonly employed for training a fully connected recurrent neural network (RNN), has a drawback of slow convergence rate. In the light of this deficiency, a decision feedback recurrent neural equalizer (DFRNE) using the RTRL requires long training sequences to achieve good performance. In this paper, extended Kalman filter (EKF) algorithms based on the RTRL for the DFRNE are presented in state-space formulation of the system, in particular for complex-valued signal processing. The main features of global EKF and decoupled EKF algorithms are fast convergence and good tracking performance. Through nonlinear channel equalization, performance of the DFRNE with the EKF algorithms is evaluated and compared with that of the DFRNE with the RTRL.
Keywords :
Kalman filters; convergence; decision feedback equalisers; learning (artificial intelligence); nonlinear filters; recurrent neural nets; state-space methods; telecommunication computing; decision feedback recurrent neural equalization; extended Kalman filter; fast convergence rate; real time recurrent learning; state space formulation; Convergence; Decision feedback equalizers; Finite impulse response filter; IIR filters; Intersymbol interference; Neural networks; Neurofeedback; Nonlinear distortion; Recurrent neural networks; Signal processing algorithms; Channel equalization; extended Kalman filter (EKF); real-time recurrent learning (RTRL); recurrent neural network (RNN); time-varying channel; Algorithms; Computer Simulation; Decision Support Techniques; Feedback; Models, Statistical; Neural Networks (Computer); Numerical Analysis, Computer-Assisted; Pattern Recognition, Automated; Signal Processing, Computer-Assisted; Stochastic Processes;
Journal_Title :
Neural Networks, IEEE Transactions on
DOI :
10.1109/TNN.2005.845142
