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Abstract
We consider the Cramer-Rao bound (CRB) for data-aided channel estimation for OFDM with known symbol padding (KSP-OFDM). The pilot symbols used to estimate the channel are positioned not only in the guard interval but also on some of the OFDM carriers, in order to improve the estimation accuracy for a given guard interval length. As the true CRB is very hard to evaluate, we derive an approximate analytical expression for the CRB, that is, the Gaussian CRB (GCRB), which is accurate for large block sizes. This derivation involves an invertible linear transformation of the received samples, yielding an observation vector of which a number of components are (nearly) independent of the unknown information-bearing data symbols. The low SNR limit of the GCRB is obtained by ignoring the presence of the data symbols in the received signals. At high SNR, the GCRB is mainly determined by the observations that are (nearly) independent of the data symbols; the additional information provided by the other observations is negligible. Both SNR limits are inversely proportional to the SNR. The GCRB is essentially independent of the FFT size and the used pilot sequence, and inversely proportional to the number of pilots. For a given number of pilot symbols, the CRB slightly increases with the guard interval length. Further, a low complexity ML-based channel estimator is derived from the observation subset that is (nearly) independent of the data symbols. Although this estimator exploits only a part of the observation, its mean-squared error (MSE) performance is close the CRB for a large range of SNR. However, at high SNR, the MSE reaches an error floor caused by the residual presence of data symbols in the considered observation subset.
Highlights
Multicarrier systems have received considerable attention for high data rate communications [1] because of their robustness to channel dispersion
We derive an approximative analytical expression for the Gaussian Cramer-Rao bound (GCRB) for channel estimation when the pilot symbols are distributed over the guard interval and pilot carriers
We have derived an approximation for the Cramer Rao bound, that is, the Gaussian Cramer-Rao bound, related to for data-aided channel estimation in KSP-OFDM, when the pilot symbols are distributed over the guard interval and pilot carriers
Summary
Multicarrier systems have received considerable attention for high data rate communications [1] because of their robustness to channel dispersion. In OFDM with known symbol padding, (KSP-OFDM), which is considered in this paper, the guard interval consists of a number of known samples [3,4,5]. In KSP-OFDM, the known samples from the guard interval can serve as pilot symbols to obtain a data-aided estimate of the channel. As the length of the guard interval is typically small as compared to the FFT length (to keep the efficiency of the multicarrier system as high as possible) the number of known samples is typically too small to obtain an accurate channel estimate. EURASIP Journal on Wireless Communications and Networking and replacing in the data part of the signal some data carriers by pilot carriers As the former strategy results in a stronger reduction of the OFDM system efficiency than the latter [8], the latter strategy will be considered.
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