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引用次数: 2
摘要
提出了基于多光谱的盲均衡的两个缺点。第一个弱点涉及零强迫(ZF)特性,在忽略相关均方误差(MSE)的情况下消除了符号间干扰。结果表明,对于在有色高斯噪声中运行的信号,可以添加最小最小均方误差(MMSE)约束,在某些情况下,计算复杂度只会略有增加,性能也会有所提高。第二个缺点涉及到信号是平稳的约束,它不能利用大多数通信信号的周期平稳特性(W. A. Gardner)。特别是,研究表明,基于多光谱的技术可以与分数间隔均衡器一起使用,从而提高时序不灵敏度(S. H. Qureshi, 1985)和受损光谱恢复(W. a . Gardner, 1991)的性能。该技术将信号分解为平稳流,计算各分区的单独统计量和联合统计量,然后求解最优维纳方程。
Polyspectra-based, blind, MMSE, fractionally-spaced equalization of a cyclostationary signal
Two weaknesses of polyspectra-based blind equalization are addressed. The first weakness involves a zero-forcing (ZF) characteristic, where intersymbol interference is eliminated with disregard for associated mean squared error (MSE). It is shown that a minimum-MSE (MMSE) constraint can be added for signals operating in colored Gaussian noise, with only a small increase in computational complexity and with performance enhancement under certain scenarios. The second weakness involves the constraint that the signal be stationary, which fails to exploit the cyclostationary features of most communication signals (W. A. Gardner). In particular, it is shown that polyspectra-based techniques can be used with a fractionally-spaced equalizer, with attendant performance boosts in timing insensitivity (S. H. Qureshi, 1985) and damaged-spectrum restoration (W. A. Gardner, 1991). The technique decomposes the signal into stationary streams, computing the individual and joint statistics of the partitions, and then solves the optimal Wiener equation.<>
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