DocumentCode
3272739
Title
Adaptive equalization with RLS-MLSE for fast fading mobile radio channels
Author
Yoshino, Hitoshi ; Fukawa, Kazuhiko ; Suzuki, Hiroshi
Author_Institution
NTT Radio Commun. Syst. Lab., Yokosuka, Japan
Volume
2
fYear
1992
fDate
10-13 May 1992
Firstpage
501
Abstract
The authors derive a novel adaptive equalization scheme from the maximum likelihood estimation theory. This scheme estimates the transmitted signal sequence from the received signal sequence which may suffer from multiplicative time-varying fading and additive white Gaussian noise. Time-varying fading is characterized as a simple Markov Gaussian process. The new scheme is a combination of the recursive least squares adaptation algorithm and maximum likelihood sequence estimation (RLS-MLSE) technique. The authors also report on the performance of the proposed RLS-MLSE as evaluated through laboratory experiments. An RLS-MLSE prototype is developed with a single-chip digital signal processor (DSP) to assess the feasibility of RLS-MLSE´s application to 42 kb/s 3-channel TDMA (time division multiple access) mobile radio QPSK transmission in the 900 MHz band under frequency-selective fast fading environments. Experimental results show that RLS-MLSE is superior to a recursive least squares decision feedback equalizer
Keywords
Markov processes; adaptive filters; digital radio systems; diversity reception; equalisers; fading; maximum likelihood estimation; mobile radio systems; parameter estimation; phase shift keying; telecommunication channels; time division multiple access; 42 kbit/s; 900 MHz; AWGN; Markov Gaussian process; QPSK transmission; RLS-MLSE; TDMA; UHF; adaptive equalization; additive white Gaussian noise; digital signal processor; fast fading; frequency selective fading; maximum likelihood sequence estimation; mobile radio channels; multiplicative time-varying fading; received signal sequence; recursive least squares adaptation; single chip DSP; time division multiple access; transmitted signal sequence; Adaptive equalizers; Additive white noise; Estimation theory; Fading; Gaussian processes; Land mobile radio; Least squares approximation; Maximum likelihood estimation; Signal processing algorithms; Time division multiple access;
fLanguage
English
Publisher
ieee
Conference_Titel
Circuits and Systems, 1992. ISCAS '92. Proceedings., 1992 IEEE International Symposium on
Conference_Location
San Diego, CA
Print_ISBN
0-7803-0593-0
Type
conf
DOI
10.1109/ISCAS.1992.230145
Filename
230145
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