TY - GEN
T1 - Performance analysis of MIMO cellular network with channel estimation errors
AU - Wen, Chao Kai
AU - Chen, Jung Chieh
AU - Ting, Pangan
AU - Hsiao, Cheng Yueh
AU - Jian, Yung Yih
AU - Hsu, Jen Yuan
PY - 2006
Y1 - 2006
N2 - In this paper, we are interested in performance analyses of a multiple-input multiple-output (MIMO) multiple-access (MA) wireless network where Wyner's linear cellular array model is adopted. Notwithstanding some recent results have shown that, in the Wyner's model, the joint processing of the entire received signal with access point (AP) cooperation can dramatically enhance the system throughput because of the macrodiversity. However, in practice, the channel estimation quality from the providers of the macrodiversity is usually poor. Furthermore, existing literatures do not take channel estimation error into account. The channel estimation error provides us the motive to derive analytical solutions to the large-system throughput (or channel sum-rate) of the MIMO cellular network with imperfect channel estimations. Unlike the most large-system results, our derived results can not only be applied in the scenarios with any given input distributions (not necessarily Gaussian) from the mobile transmitters, but also clarify the performance of the network which was originally involved. Several issues we address including 1) how much of coherence interval should be spent for training and 2) the impact of AP cooperation is highlighted through the analytical results.
AB - In this paper, we are interested in performance analyses of a multiple-input multiple-output (MIMO) multiple-access (MA) wireless network where Wyner's linear cellular array model is adopted. Notwithstanding some recent results have shown that, in the Wyner's model, the joint processing of the entire received signal with access point (AP) cooperation can dramatically enhance the system throughput because of the macrodiversity. However, in practice, the channel estimation quality from the providers of the macrodiversity is usually poor. Furthermore, existing literatures do not take channel estimation error into account. The channel estimation error provides us the motive to derive analytical solutions to the large-system throughput (or channel sum-rate) of the MIMO cellular network with imperfect channel estimations. Unlike the most large-system results, our derived results can not only be applied in the scenarios with any given input distributions (not necessarily Gaussian) from the mobile transmitters, but also clarify the performance of the network which was originally involved. Several issues we address including 1) how much of coherence interval should be spent for training and 2) the impact of AP cooperation is highlighted through the analytical results.
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U2 - 10.1109/VTCF.2006.177
DO - 10.1109/VTCF.2006.177
M3 - Conference contribution
AN - SCOPUS:34548843379
SN - 1424400635
SN - 9781424400638
T3 - IEEE Vehicular Technology Conference
SP - 821
EP - 825
BT - 2006 IEEE 64th Vehicular Technology Conference, VTC-2006 Fall
T2 - 2006 IEEE 64th Vehicular Technology Conference, VTC-2006 Fall
Y2 - 25 September 2006 through 28 September 2006
ER -