A high throughput rate and low circuit complexity QAM channel equalizer design based on bit serial scheme

1999 IEEE Workshop on Signal Processing Systems. SiPS 99. Design and Implementation (Cat. No.99TH8461) Pub Date : 1999-10-20 DOI:10.1109/SIPS.1999.822362

Y. Hwang, Wei-Cheng Lin

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引用次数: 3

Abstract

In this paper, a novel VLSI design for an all digital QAM channel equalizer is presented. We adopted a decision-feedback equalizer (DFE) structure to combat the inter-symbol-interference (ISI) induced during high speed data communication. The equalizer consists mainly of eight transversal adaptive filters and slicers. Since the adaptive filter along with the slicer will form a nonlinear feedback path, the resultant recursive computing often leads to a severe performance bottleneck. To overcome this, a bit serial, MSB first computing scheme based on distributed arithmetic and signed digit number system techniques was developed. In our scheme, the next symbol's equalization can be started as soon as the MSD of the current symbol is obtained. This leads to a computation overlap between successive symbol's equalization and can effectively improve the baud rate. The circuit complexity, however, is still kept low with the help of fine grain pipelining. With careful arrangement of data flow, an efficient systolic array design with 100% utilization and suitable for VLSI implementation is derived. The design architecture is also scalable in that the initiation interval between the processing of two consecutive symbols is a constant of 5+[m/4] clocks (in the delayed sign LMS case) and the hardware complexity is of order 2/spl middot/m/spl middot/(n+1), where m and n are tap order and word length.

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基于位串行方案的高吞吐率、低电路复杂度的QAM信道均衡器设计

本文提出了一种全数字QAM信道均衡器的VLSI设计方案。我们采用决策反馈均衡器(DFE)结构来对抗高速数据通信中产生的符号间干扰(ISI)。均衡器主要由八个横向自适应滤波器和切片器组成。由于自适应滤波器与切片器将形成非线性反馈路径，由此产生的递归计算常常导致严重的性能瓶颈。为解决这一问题，提出了一种基于分布式算法和符号数字系统技术的位串行、MSB优先计算方案。在我们的方案中，只要获得当前符号的MSD，就可以启动下一个符号的均衡。这使得连续的码元均衡化之间的计算重叠，可以有效地提高波特率。然而，在细粒度流水线的帮助下，电路的复杂性仍然保持在较低水平。通过对数据流的精心安排，推导出一种具有100%利用率、适合VLSI实现的高效收缩阵列设计。该设计架构还具有可扩展性，因为处理两个连续符号之间的起始间隔为5+[m/4]个时钟(在延迟符号LMS情况下)，硬件复杂度为2/spl middot/m/spl middot/(n+1)阶，其中m和n为分接顺序和单词长度。

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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来源期刊

1999 IEEE Workshop on Signal Processing Systems. SiPS 99. Design and Implementation (Cat. No.99TH8461)

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