Title :
Mismatched finite-complexity MMSE decision feedback equalizers
Author :
Al-Dhahir, Naofal ; Cioffi, John M.
Author_Institution :
Gen. Electr. Corp. Res. & Dev. Center, Schenectady, NY, USA
fDate :
4/1/1997 12:00:00 AM
Abstract :
Closed-form expressions that quantify the degradation in the decision-point signal-to-noise ratio of the finite-length minimum mean-square-error decision feedback equalizer (MMSE-DFE) due to channel and noise mismatch conditions are derived. The analysis is further extended to other receiver structures, namely, the MMSE-DFE with an adaptive feedforward filter, the MMSE linear equalizer, and the discrete multitone transceiver, all under a finite-complexity constraint. The limiting case of infinite-length filters is also analyzed. In addition, we present computer simulation results that compare the performance of the various receiver structures under study, assuming a particular channel and noise mismatch model for the high-bit-rate digital subscriber loop environment. Finally, several methods that can be used to mitigate the effects of mismatch are outlined
Keywords :
FIR filters; adaptive filters; adaptive signal processing; decision feedback equalisers; feedforward; filtering theory; noise; receivers; subscriber loops; telecommunication channels; transceivers; MMSE linear equalizer; MMSE-DFE; adaptive feedforward filter; channel mismatch; closed-form expressions; computer simulation results; decision feedback equalizer; decision-point signal-to-noise ratio; discrete multitone transceiver; finite-complexity constraint; high bit rate digital subscriber loop; infinite-length filters; minimum mean square error; mismatched finite-complexity MMSE DFE; noise mismatch; performance; receiver structures; Adaptive filters; Closed-form solution; Computer simulation; DSL; Decision feedback equalizers; Degradation; Nonlinear filters; Signal to noise ratio; Transceivers; Working environment noise;
Journal_Title :
Signal Processing, IEEE Transactions on
