Author_Institution :
Dipt. di Elettron. e Inf., Politec. di Milano, Milan, Italy
Abstract :
For additive white Gaussian noise (AWGN) channels, first we show that the conditional probability distribution of the symbol error ratio (BER), in n transmitted symbols, can be modeled as lognormal in BPSK, QPSK and QAM transmission schemes, for a given average probability of symbol error p, and then we show that the channel signal-to-noise ratio (SNR), conditioned to p, can be modeled as a Gaussian random variable, as long as p>;>;1, n>;>;1, np≥1000. The theoretical results could be useful in assessing bounds to the estimated SNR in terrestrial, satellite or deep-space AWGN channels. Moreover, from the estimated SNR, it should be possible to estimate the fading due to slow tropospheric phenomena, such as rain, water vapor, oxygen attenuation.
Keywords :
AWGN channels; error statistics; quadrature amplitude modulation; quadrature phase shift keying; statistical distributions; BER measurements; BPSK; Gaussian random variable; QAM transmission schemes; QPSK; SNR; additive white Gaussian noise channels; channel signal-to-noise ratio; deep-space AWGN channels; oxygen attenuation; probability distribution; signal-to-noise ratio; symbol error ratio; tropospheric phenomena; water vapor; Bit error rate; Channel estimation; Decoding; Quadrature amplitude modulation; Random variables; Signal to noise ratio;
