Source fidelity over fading channels: erasure codes versus scalable codes

GLOBECOM '05. IEEE Global Telecommunications Conference, 2005. Pub Date : 2005-12-01 DOI:10.1109/GLOCOM.2005.1578223

K. Zachariadis, M. Honig, A. Katsaggelos

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引用次数: 11

Abstract

We consider the transmission of a Gaussian source through a block fading channel. Assuming each block is decoded independently, the received distortion depends on the tradeoff between quantization accuracy and probability of outage. Namely, higher quantization accuracy requires a higher channel code rate, which increases the probability of outage. Here we evaluate the received mean distortion with erasure coding across blocks as a function of the code length. We also evaluate the performance of scalable, or multi-resolution coding in which coded layers are superimposed, and the layers are sequentially decoded. In addition to analyzing a finite number of layers, we evaluate the mean distortion at high signal-to-noise ratios as the number of layers becomes infinite. As the block length of the erasure code increases to infinity, the received distortion converges to a deterministic limit, which is less than the mean distortion with an infinite-layer scalable coding scheme. However, for the same standard deviation in received distortion, infinite layer scalable coding performs slightly better than erasure coding

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衰落信道上的信源保真度:擦除码与可扩展码

我们考虑高斯源在块衰落信道中的传输。假设每个块被独立解码，接收到的失真取决于量化精度和中断概率之间的权衡。也就是说，更高的量化精度要求更高的信道码率，这就增加了中断的概率。在这里，我们评估接收到的平均失真与跨块的擦除编码作为代码长度的函数。我们还评估了可扩展或多分辨率编码的性能，其中编码层是叠加的，并且这些层是顺序解码的。除了分析有限层数外，我们还评估了当层数变为无限时，高信噪比下的平均失真。当纠删码的块长度增加到无穷大时，接收到的失真收敛于一个确定性极限，该极限小于无限层可扩展编码方案的平均失真。然而，对于接收失真的相同标准差，无限层可扩展编码的性能略好于擦除编码

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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GLOBECOM '05. IEEE Global Telecommunications Conference, 2005.

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