Pilot Design and Doubly-Selective Channel Estimation for Faster-than-Nyquist Signaling

Simin Keykhosravi, E. Bedeer
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Abstract

Being capable of enhancing the spectral efficiency (SE), faster-than-Nyquist (FTN) signaling is a promising approach for wireless communication systems. This paper investigates the doubly-selective (i.e., time- and frequency-selective) channel estimation and data detection of FTN signaling. We consider the intersymbol interference (ISI) resulting from both the FTN signaling and the frequency-selective channel and adopt an efficient frame structure with reduced overhead. We propose a novel channel estimation technique of FTN signaling based on the least sum of squared errors (LSSE) approach to estimate the complex channel coefficients at the pilot locations within the frame. In particular, we find the optimal pilot sequence that minimizes the mean square error (MSE) of the channel estimation. To address the time-selective nature of the channel, we use a low-complexity linear interpolation to track the complex channel coefficients at the data symbols locations within the frame. To detect the data symbols of FTN signaling, we adopt a turbo equalization technique based on a linear soft-input soft-output (SISO) minimum mean square error (MMSE) equalizer. Simulation results show that the MSE of the proposed FTN signaling channel estimation employing the designed optimal pilot sequence is lower than its counterpart designed for conventional Nyquist transmission. The bit error rate (BER) of the FTN signaling employing the proposed optimal pilot sequence shows improvement compared to the FTN signaling employing the conventional Nyquist pilot sequence. Additionally, for the same SE, the proposed FTN signaling channel estimation employing the designed optimal pilot sequence shows better performance when compared to competing techniques from the literature.
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比奈奎斯特信号更快的导频设计和双选择信道估计
比奈奎斯特(FTN)更快信号具有提高频谱效率(SE)的能力,是一种很有前途的无线通信方法。本文研究了FTN信令的双选择性(即时间和频率选择性)信道估计和数据检测。我们考虑了由FTN信令和频率选择信道引起的码间干扰(ISI),并采用了减少开销的高效帧结构。提出了一种基于最小平方误差和(LSSE)方法的FTN信令信道估计技术,用于估计帧内导频位置的复杂信道系数。特别是,我们找到了使信道估计的均方误差(MSE)最小的最优导频序列。为了解决信道的时间选择性,我们使用低复杂度线性插值来跟踪帧内数据符号位置的复杂信道系数。为了检测FTN信令的数据符号,我们采用了基于线性软输入软输出(SISO)最小均方误差(MMSE)均衡器的turbo均衡技术。仿真结果表明,采用所设计的最优导频序列估计的FTN信令信道的MSE低于传统奈奎斯特传输的MSE。与采用传统奈奎斯特导频序列的FTN信令相比,采用所提出的最优导频序列的FTN信令的误码率(BER)有所改善。此外,对于相同的SE,与文献中的竞争技术相比,采用设计的最优导频序列的FTN信令信道估计显示出更好的性能。
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