TY - GEN
T1 - Operation range estimation of reed-solomon coded SC-FDE system in 60-GHz WPANs
AU - Baykas, Tuncer
AU - Lei, Ming
AU - Sum, Chin Sean
AU - Funada, Ryuhei
AU - Nishiguchi, Yoshinori
AU - Kimura, Ryota
AU - Wang, Jun Yi
AU - Rahman, Azizur
AU - Harada, Hiroshi
AU - Kato, Shuzo
PY - 2008
Y1 - 2008
N2 - 60-GHz band is a popular choice of industry for next generation wireless personal area networks, which will enable data rates in the order of Gbps. Single-carrier frequency domain equalization (SC-FDE) systems are proposed to obtain such high data rates in low-power and low-cost consumer products. In this paper, we are suggesting to use simple zero-forcing equalization to reduce the complexity requirement. We test system performance through simulations and And associated range of the WPAN. Our simulations take into account non-line-of-sight (NLOS) multipath channel model, channel estimation errors and RF impairments of phase noise and power amplifier distortion, to obtain realistic results. Our results show zero-forcing equalization can be employed in applications robust to delay such as file transfer between PCs and peripherals up to 4 meters. This result encourages the usage of 60-GHz band in low-power devices such as cellular phones and cameras. For applications which are sensitive to delay such as video streaming, more complex MMSE equalizer is required.
AB - 60-GHz band is a popular choice of industry for next generation wireless personal area networks, which will enable data rates in the order of Gbps. Single-carrier frequency domain equalization (SC-FDE) systems are proposed to obtain such high data rates in low-power and low-cost consumer products. In this paper, we are suggesting to use simple zero-forcing equalization to reduce the complexity requirement. We test system performance through simulations and And associated range of the WPAN. Our simulations take into account non-line-of-sight (NLOS) multipath channel model, channel estimation errors and RF impairments of phase noise and power amplifier distortion, to obtain realistic results. Our results show zero-forcing equalization can be employed in applications robust to delay such as file transfer between PCs and peripherals up to 4 meters. This result encourages the usage of 60-GHz band in low-power devices such as cellular phones and cameras. For applications which are sensitive to delay such as video streaming, more complex MMSE equalizer is required.
KW - 60 GHz
KW - IEEE802.15.3c
KW - Millimeter-wave
KW - WPAN
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U2 - 10.1109/ICACT.2008.4493735
DO - 10.1109/ICACT.2008.4493735
M3 - Conference contribution
AN - SCOPUS:44249093296
SN - 9788955191356
T3 - International Conference on Advanced Communication Technology, ICACT
SP - 167
EP - 170
BT - 10th International Conference on Advanced Communication Technology, ICACT 2008 - Proceedings
T2 - 2008 10th International Conference on Advanced Communication Technology
Y2 - 17 February 2008 through 20 February 2008
ER -