Block-coded 16TAPSK and 16QAM for generalized differential encoding

2012 12th International Conference on ITS Telecommunications Pub Date : 2012-11-01 DOI:10.1109/ITST.2012.6425270

Tzu-Shiang Lin

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Abstract

In this paper, we consider noncoherent block-coded QAM (quadrature-amplitude modulation) and TAPSK (twisted amplitude and phase shift keying) for generalized differential encoding. For noncoherent block-coded MPSK over continuous channels, rotating signal points of an entire codeword, such that the first symbol is the same as the last symbol of previously transmitted codeword and thus can be omitted, increase bandwidth efficiency. This method is called generalized differential encoding. Since noncoherent block-coded QAM/TAPSK proposed before cannot be applied to generalized differential encoding, in this paper, we modify the definition of noncoherent block-coded QAM/TAPSK and the bit labeling of signal points. Simulations of various examples of noncoherent block-coded QAM/TAPSK with generalized differential encoding are made and discussed as well. We find that if the block length is very small than 8, NBC-16TAPSK performs better than NBC-16QAM due to its large minimum noncoherent distance. However, if the block is longer than 8, NBC-16QAM has better error performance because the codewords with small noncoherent distances are rare.

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块编码16TAPSK和16QAM广义差分编码

在本文中，我们考虑非相干块编码QAM(正交幅度调制)和TAPSK(扭曲幅度和相移键控)用于广义差分编码。对于连续信道上的非相干块编码MPSK，旋转整个码字的信号点，使第一个符号与先前传输的码字的最后一个符号相同，从而可以省略，从而提高带宽效率。这种方法被称为广义差分编码。由于之前提出的非相干块编码QAM/TAPSK不能应用于广义差分编码，本文对非相干块编码QAM/TAPSK的定义和信号点的位标记进行了修改。文中还对采用广义差分编码的非相干块编码QAM/TAPSK进行了仿真。我们发现，当块长度小于8时，由于NBC-16TAPSK具有较大的最小非相干距离，因此其性能优于NBC-16QAM。但是，当块长度大于8时，NBC-16QAM具有更好的错误性能，因为具有较小非相干距离的码字很少。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2012 12th International Conference on ITS Telecommunications

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