An idealized computer simulation of an equalizer using two-ray and measurement-based channel impulse response models is presented. A decision feedback equalizer (DFE) with a recursive least squares (RLS) algorithm is used as the equalization scheme. The results show that adaptive equalization can significantly improve the bit-error-rate (BER) of a mobile system if the channel does not change too rapidly. The simulation shows that in a two-ray Rayleigh fading channel, if the delay of the second ray is too small, then adaptive equalization will degrade the BER performance. The value of the delay at which the adaptive equalizer can improve the BER depends on the normalized Doppler frequency. A mobile channel simulator is used to show how much the equalizer can improve the BER in real-world urban channels. The performance of adaptive equalization for indoor high-data-rate systems is evaluated. An equalization structure for pi /4 DQPSK modulation is developed, and simulation results are presented.<<ETX>>
[1]
G. D'Aria,et al.
Results on fast-Kalman and Viterbi adaptive equalizers for mobile radio with CEPT/GSM system characteristics
,
1988,
IEEE Global Telecommunications Conference and Exhibition. Communications for the Information Age.
[2]
W. C. Jakes,et al.
Microwave Mobile Communications
,
1974
.
[3]
Theodore S. Rappaport,et al.
Statistical channel impulse response models for factory and open plan building radio communicate system design
,
1991,
IEEE Trans. Commun..
[4]
J.E. Mazo,et al.
Digital communications
,
1985,
Proceedings of the IEEE.
[5]
Ii Leon W. Couch.
Digital and analog communication systems
,
1983
.
[6]
T. Rappaport.
Characterization of UHF multipath radio channels in factory buildings
,
1989
.