This paper presents a parallel architecture for a high-speed Reed-Solomon (RS) encoder and decoder (codec) LSI. Since the architecture allows H symbols to be processed in parallel the codec LSI achieves a data rate of mLH b/s. where m is the symbol size (m bits per symbol), L is the clock frequency of the circuit, and H is an arbitrary integer. As an example, we investigate hardware complexity, delay and critical path length for a (255.251) RS code. It is shown that both the hardware complexity and the delay for a parallel circuit is much less than that with the parallel operation of H conventional circuits. Although the only problem with, this parallel architecture is that the encoder's critical path length increases with H, the proposed architectures is more efficient than a setup using H conventional circuits for high data rate applications. It is also suggested that parallel RS codecs, which can keep up with optical transmission rates, i.e. several giga bits/sec. could be implemented on one LSI chip, using current CMOS technology.
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机译:本文提出了一种高速Reed-Solomon(RS)编码器和解码器(codec)LSI的并行架构。由于该架构允许并行处理H个符号,因此编解码器LSI的数据速率为mLH b / s。其中,m是符号大小(每个符号m位),L是电路的时钟频率,H是任意整数。例如,我们调查(255.251)RS代码的硬件复杂性,延迟和关键路径长度。结果表明,并行电路的硬件复杂度和延迟都远小于H常规电路的并行操作。尽管这种并行架构的唯一问题是编码器的关键路径长度随H的增加而增加,但对于高数据速率应用,所提出的架构比使用H常规电路的设置更为有效。还建议使用并行RS编解码器,它可以跟上光学传输速率,即几吉比特/秒。可以使用当前的CMOS技术在一个LSI芯片上实现。
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