DocumentCode
1138109
Title
Performance of Quantized Equal Gain Transmission With Noisy Feedback Channels
Author
Murthy, Chandra R. ; Zheng, Jun ; Rao, Bhaskar D.
Author_Institution
Dept. of Electr. & Comput. Eng., Indian Inst. of Sci., Bangalore
Volume
56
Issue
6
fYear
2008
fDate
6/1/2008 12:00:00 AM
Firstpage
2451
Lastpage
2460
Abstract
In this paper, new results and insights are derived for the performance of multiple-input, single-output systems with beamforming at the transmitter, when the channel state information is quantized and sent to the transmitter over a noisy feedback channel. It is assumed that there exists a per-antenna power constraint at the transmitter, hence, the equal gain transmission (EGT) beamforming vector is quantized and sent from the receiver to the transmitter. The loss in received signal-to-noise ratio (SNR) relative to perfect beamforming is analytically characterized, and it is shown that at high rates, the overall distortion can be expressed as the sum of the quantization-induced distortion and the channel error-induced distortion, and that the asymptotic performance depends on the error-rate behavior of the noisy feedback channel as the number of codepoints gets large. The optimum density of codepoints (also known as the point density) that minimizes the overall distortion subject to a boundedness constraint is shown to be the same as the point density for a noiseless feedback channel, i.e., the uniform density. The binary symmetric channel with random index assignment is a special case of the analysis, and it is shown that as the number of quantized bits gets large the distortion approaches the same as that obtained with random beamforming. The accuracy of the theoretical expressions obtained are verified through Monte Carlo simulations.
Keywords
Monte Carlo methods; array signal processing; quantisation (signal); telecommunication channels; Monte Carlo simulation; asymptotic performance; beamforming; channel error-induced distortion; feedback channel; multiple-input single-output system; quantization-induced distortion; quantized equal gain transmission; signal-to-noise ratio; Channel state quantization; equal gain transmission; feedback communication;
fLanguage
English
Journal_Title
Signal Processing, IEEE Transactions on
Publisher
ieee
ISSN
1053-587X
Type
jour
DOI
10.1109/TSP.2007.914967
Filename
4494457
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