Title :
Coherent MAP detection of DQPSK bits
Author :
Bottomley, Gregory E. ; Arslan, Hüseyin ; Ramésh, R. ; Brismark, Gustav
Author_Institution :
Ericsson Inc., NC, USA
Abstract :
Both IS-136 and PDC digital cellular systems employ forward error correction (FEC) encoding followed by a form of DQPSK modulation. In this letter, we derive the maximum a posteriori (MAP) bit detector for DQPSK modulation in non-ISI channels for a coherent receiver with one or more antennas. The MAP detector forms a bit log-likelihood ratio, which provides the optimal "soft information" for MLSE or MAP convolutional decoding. MAP detection requires exponentiation and logarithm operations, as well as knowledge of the noise covariance. To avoid these operations, two approximate forms are developed, which do not require the noise covariance value under certain assumptions. Both approximate approaches, when used with soft FEC decoding, are within 0.5 dB of the optimal approach.
Keywords :
cellular radio; convolutional codes; differential phase shift keying; digital radio; forward error correction; maximum likelihood decoding; maximum likelihood detection; maximum likelihood sequence estimation; quadrature phase shift keying; radio receivers; DQPSK bits; DQPSK modulation; FEC encoding; IS-136; MAP convolutional decoding; MAP detection; MLSE; PDC; antennas; approximate forms; bit log-likelihood ratio; coherent MAP detection; coherent receiver; digital cellular systems; forward error correction; maximum a posteriori bit detector; nonISI channels; soft FEC decoding; soft information; Decision feedback equalizers; Demodulation; Detectors; Digital modulation; Forward error correction; Intersymbol interference; Maximum likelihood decoding; Maximum likelihood estimation; Phase detection; Quadrature phase shift keying;
Journal_Title :
Communications Letters, IEEE
DOI :
10.1109/4234.892200
