Title :
Interior point least squares estimation: transient convergence analysis and application to MMSE decision-feedback equalization
Author :
Afkhamie, Kaywan H. ; Luo, Zhi-Quan ; Wong, Kon Max
Author_Institution :
Intellon Corp., Ocala, FL, USA
fDate :
7/1/2001 12:00:00 AM
Abstract :
In many communication systems, training sequences are used to help the receiver identify and/or equalize the channel. The amount of training data required depends on the convergence properties of the adaptive filtering algorithms used for equalization. In this paper, we propose the use of a new adaptive filtering method called interior point least squares (IPLS) for adaptive equalization. First, we show that IPLS converges exponentially fast in the transient phase. Then, we use the IPLS algorithm to update the weight vector for a minimum-mean-square-error decision-feedback equalizer (MMSE-DFE) in a CDMA downlink scenario. Numerical simulations show that when training sequences are short IPLS consistently outperforms RLS in terms of system bit-error-rate and packet error rate. As the training sequence gets longer IPLS matches the performance of the RLS algorithm
Keywords :
adaptive equalisers; adaptive filters; code division multiple access; convergence of numerical methods; decision feedback equalisers; land mobile radio; least mean squares methods; packet radio networks; CDMA downlink; IPLS; MMSE decision-feedback equalization; MMSE-DFE; adaptive equalization; adaptive filtering; bit-error-rate; communication systems; interior point least squares estimation; minimum-mean-square-error decision-feedback equalizer; packet error rate; performance; training sequence; transient convergence analysis; transient phase; weight vector; Adaptive equalizers; Adaptive filters; Convergence; Decision feedback equalizers; Filtering algorithms; Least squares approximation; Least squares methods; Multiaccess communication; Resonance light scattering; Training data;
Journal_Title :
Signal Processing, IEEE Transactions on
