Title :
BER expressions for differentially detected π/4 DQPSK modulation
Author :
Miller, Leonard E. ; Lee, Jhong S.
Author_Institution :
J.S. Lee Assoc. Inc., Rockville, MD, USA
fDate :
1/1/1998 12:00:00 AM
Abstract :
Closed form bit-error rate (BER) expressions for differentially detected π/4-shifted differentially encoded quadrature phase-shift keying (QPSK) modulation (π/4 DQPSK) are derived for both additive white Gaussian noise (AWGN) and Rayleigh-fading channels. The derivations are carried out in an exact and most general manner in that in-phase (I) and quadrature (Q) channel bit-error probabilities Pcl and PcQ are separately obtained in terms of the same-quadrature and cross-quadrature noise Correlation functions, including a measure of noise nonstationarity. We then specialize the general expressions for uncorrelated noise and equal noise powers in successive symbol periods to obtain a useful bit-error probability expression for the AWGN channel in the form Pe≈Q(√(1.1716·Eb/N0)) where Q(·) is the Gaussian distribution Q-function and Eb /N0 is the bit energy-to-noise density ratio. Exact BER expressions for the Rayleigh-fading channel that involve the noise parameters are also given and are extended to the case of L-fold diversity combining
Keywords :
Gaussian channels; Gaussian distribution; Rayleigh channels; cellular radio; coding errors; correlation methods; demodulation; differential phase shift keying; digital radio; diversity reception; error statistics; fading; land mobile radio; modulation coding; quadrature phase shift keying; time division multiple access; AWGN channel; Gaussian distribution Q-function; Rayleigh-fading channel; TDMA; additive white Gaussian noise; bit energy-to-noise density ratio; bit-error probabilities; bit-error probability; closed form BER expressions; cross-quadrature noise correlation function; differentially detected π/4 DQPSK modulation; differentially encoded quadrature phase-shift keying; digital cellular radio; diversity combining; equal noise power; exact BER expressions; in-phase channel; noise nonstationarity; noise parameters; quadrature channel; same-quadrature correlation function; uncorrelated noise power; AWGN; Additive white noise; Bit error rate; Diversity reception; Gaussian noise; Phase detection; Phase shift keying; Quadrature phase shift keying; Rayleigh channels; Signal to noise ratio;
Journal_Title :
Communications, IEEE Transactions on
