Title :
An implementation of a CMA adaptive array for high speed GMSK transmission in mobile communications
Author :
Ohgane, Takeo ; Shimura, Takanori ; Matsuzawa, Naoto ; Sasaoka, Hideichi
Author_Institution :
Commun. Res. Lab., Minist. of Posts & Telecommun., Tokyo, Japan
fDate :
8/1/1993 12:00:00 AM
Abstract :
The hardware implementation of an adaptive array as a technique for compensating multipath fading in mobile communications is described. The number of the antenna elements is four. The target communication system is modulated by 256 kbps Gaussian-filtered minimum shift keying (MSK) and has a time-division multiplexing (TDM) architecture with 24 time slots. Based on the digital beamforming concept, all of the signals and the array weights are digital-signal processed. The constant modulus algorithm (CMA) is employed for weight optimizing. In an additive white Gaussian noise channel, this system has 5.6-dB gain in an energy-per-bit-to-noise-density ratio at a bit error rate (BER) of 1.0×10-3, compared with a single antenna system. The result of the basic field test shows that the gain at a BER of 1.0×10-3 reaches 22.3 dB in a nonselective, slow Rayleigh fading channel given a 5 Hz maximum Doppler shift
Keywords :
antenna phased arrays; array signal processing; digital radio systems; fading; interference suppression; minimum shift keying; mobile radio systems; telecommunication channels; time division multiplexing; white noise; 22.3 dB; 256 kbit/s; 5.6 dB; AWGN channel; BER; Doppler shift; Gaussian-filtered minimum shift keying; adaptive array; additive white Gaussian noise channel; antenna elements; array weights; bit error rate; constant modulus algorithm; digital beamforming concept; digital mobile radio; energy-per-bit-to-noise-density ratio; hardware implementation; high speed GMSK transmission; mobile communications; multipath fading; slow Rayleigh fading channel; time-division multiplexing; Adaptive arrays; Additive white noise; Array signal processing; Bit error rate; Fading; Gaussian processes; Hardware; Mobile communication; Signal processing; Time division multiplexing;
Journal_Title :
Vehicular Technology, IEEE Transactions on
