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Frequency Synchronization in Distributed Antenna Systems: Pairing-Based Multi-CFO Estimation, Theoretical Analysis, and Optimal Pairing Scheme | IEEE Journals & Magazine | IEEE Xplore
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Frequency Synchronization in Distributed Antenna Systems: Pairing-Based Multi-CFO Estimation, Theoretical Analysis, and Optimal Pairing Scheme

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Yunqi Feng; Weile Zhang; Yinghao Ge; Hai Lin
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Abstract:

In this paper, we consider the frequency synchronization issue in orthogonal frequency division multiplexing distributed antenna systems. There may exist multiple carrier...Show More

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Abstract:

In this paper, we consider the frequency synchronization issue in orthogonal frequency division multiplexing distributed antenna systems. There may exist multiple carrier frequency offsets (CFOs) between the transmitter and distributed receive antennas. To solve the multi-CFO estimation problem, we first derive the blind maximum likelihood estimator, which has superior estimation performance, but exhibits high computational complexity. Furthermore, we develop a blind pairing-based efficient estimator (PBEE), which divides the multiple antennas into pairs of two. The two CFOs in each pair are jointly estimated with a carefully designed cost function, which proves to be exactly a cosine function parameterized by the two CFOs even with the effect of noise. Consequently, the joint estimation of the two CFOs can be simplified to the one-dimensional search optimization problem. The PBEE can achieve better CFO estimation performance than the existing competitors. From the theoretical mean square error (MSE) analysis of PBEE, we further derive the optimal antenna pairing scheme by minimizing the signal-to-noise ratio degradation caused by the uncompensated residual CFOs. Finally, the Cramér-Rao bound of CFO estimation is derived and numerical results are provided to corroborate the proposed studies.
Published in: IEEE Transactions on Communications ( Volume: 67, Issue: 4, April 2019)
Page(s): 2924 - 2938
Date of Publication: 25 December 2018

ISSN Information:

DOI: 10.1109/TCOMM.2018.2889759

Funding Agency:

References is not available for this document.
Contents

I. Introduction

The distributed antenna systems (DAS) have been widely implemented in the wireless communication systems due to its advantages of higher sum-rate capacity, extended coverage and lower power consumption compared to the conventional co-located antenna systems (CAS) [1], [2]. Downlink performance and capacity analysis, antenna location design and resource allocation optimization problem in DAS have been extensively investigated in recent years [3]–[6]. On the other hand, orthogonal frequency division multiplexing (OFDM) is already a mature technique, owing to its high data transmission rate and immunity to the frequency-selective fading. The correlation characteristics of fading channel prevent OFDM CAS systems from fully exploiting spatial diversity and increasing capacity further. Considering that DAS could significantly improve the performance of OFDM due to the potentials of a higher spatial diversity, especially the large-scale fading diversity, it is of great benefit to study OFDM DAS. However, the carrier frequency offset (CFO) between transceivers may lead to serious performance degradation in OFDM systems [7], [8].

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