CN  Vol.2 No.4 , November 2010
Optimal Spacing Design for Pilots in OFDM Systems over Multipath Fading Channels
Abstract: In wireless orthogonal frequency division multiplexing (OFDM) systems, the time-varying channel is often estimated by algorithms based on pilot symbols. Such an estimator, however, requires statistical prior knowledge that is not easily obtained. Therefore, the pilot tones have to be close enough to fulfill the sampling theorem. In this case the statistical knowledge of the channel is not required to reconstruct correctly the channel impulse response (CIR). This paper explores the optimal placement and number of pilot symbols, we investigate optimal training sequences in OFDM systems and we analyze the number of pilot symbols required to fulfill the sampling theorem. Using a general model for a multipath slowly fading channel, the approach is based on the LS as a criterion of channel estimation while the channel interpolation is done using the piecewise-constant interpolation compromising between complexity and performance. Simulation results demonstrate the good performance of our approach.
Cite this paper: nullY. Abdelkader and E. Jamal, "Optimal Spacing Design for Pilots in OFDM Systems over Multipath Fading Channels," Communications and Network, Vol. 2 No. 4, 2010, pp. 221-229. doi: 10.4236/cn.2010.24032.

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