It has been shown that transmit correlation causes a signal-to-noise ratio (SNR) loss in the zero forcing (ZF) receiver for V-BLAST (Vertical Bell LAbs LAyered Space-Time) system. In this paper, we investigate t...It has been shown that transmit correlation causes a signal-to-noise ratio (SNR) loss in the zero forcing (ZF) receiver for V-BLAST (Vertical Bell LAbs LAyered Space-Time) system. In this paper, we investigate the transmit correlation effect on the ZF receiver with successive interference cancellation (SIC). We show that such an unfavorable condition leads to twofold effects on the performance degradation. In addition to the immediate SNR loss, the transmit correlation can increase the propagation factor to spread decision error significantly. These two effects are evaluated analytically. We derive the probability density function (pdf) of the effective SNR at each decoded stream, and hence accurately quantify the SNR loss. We also calculate the decision error propagation factor in terms of its second moment. In particular, we show that transmit correlation can cause a stable component of error propagation which does not decline during the SIC procedure. Finally, we conduct the simulation to verify the analytical results.展开更多
基金Supported in part by Shanghai Research Center for Wireless Communications (SHRCWC) cooperative projectin part by the Ministry of Science and Technology of China (Grant Nos. 2008DFA12190, 2008DFA12090)
文摘It has been shown that transmit correlation causes a signal-to-noise ratio (SNR) loss in the zero forcing (ZF) receiver for V-BLAST (Vertical Bell LAbs LAyered Space-Time) system. In this paper, we investigate the transmit correlation effect on the ZF receiver with successive interference cancellation (SIC). We show that such an unfavorable condition leads to twofold effects on the performance degradation. In addition to the immediate SNR loss, the transmit correlation can increase the propagation factor to spread decision error significantly. These two effects are evaluated analytically. We derive the probability density function (pdf) of the effective SNR at each decoded stream, and hence accurately quantify the SNR loss. We also calculate the decision error propagation factor in terms of its second moment. In particular, we show that transmit correlation can cause a stable component of error propagation which does not decline during the SIC procedure. Finally, we conduct the simulation to verify the analytical results.
