Author_Institution :
Bello Inc., Needham, MA, USA
Abstract :
This paper presents analytical and numerical results on the sample size required to achieve a specified root mean square (RMS) error in estimating the error rate for flat fading channels having complex Gaussian statistics. The analysis shows that for the large sample sizes normally used in estimating error rates, k, the required sample size normalized to the required sample size for independent symbol fading, can be expressed in the form k=1+dβ where d is the symbol rate normalized to the Doppler spread of the channel. For a given modem, β is a function of the error probability and the order of diversity. It is shown that if the Doppler spread measure used is proportional to the RMS Doppler spread, P will be relatively insensitive to the shape of the Doppler power spectrum. Numerical results are presented for Lth order diversity reception of binary phase shift keying (PSK), differential PSK, and frequency shift keying (FSK) signals and for five different Doppler power spectra. Ideal maximal ratio combining is assumed for the PSK modem, and square law combining is assumed for the DPSK and FSK modems
Keywords :
Doppler effect; Gaussian processes; coding errors; differential phase shift keying; diversity reception; error statistics; fading; frequency shift keying; modems; signal sampling; spectral analysis; statistical analysis; telecommunication channels; DPSK modem; Doppler power spectrum; Doppler spread measure; FSK modem; PSK modem; RMS Doppler spread; RMS error; binary phase shift keying; complex Gaussian statistics; differential PSK; diversity order; error probability; error rate; error-rate measurement; flat fading channels; frequency shift keying; independent symbol fading; maximal ratio combining; root mean square error; sample size; symbol rate; Diversity reception; Error analysis; Fading; Frequency shift keying; Modems; Phase shift keying; Root mean square; Shape measurement; Size measurement; Statistical analysis;
