High-Performance VLSI Architecture of Decision Feedback Equalizer for Gigabit Systems

This brief addresses the design of a decision feedback equalizer (DFE) for gigabit throughput rate. It is well known that the feedback loop in a DFE limits an upper bound of the achievable speed. For a L-tap feedbackward filter (FBF) and M-pulse amplitude modulation, Parhi (1991) and Kasturia and Wi...

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Published inIEEE transactions on circuits and systems. II, Express briefs Vol. 53; no. 9; pp. 911 - 915
Main Authors Lin, Chih-Hsiu, Wu, An-Yeu, Li, Fan-Min
Format Journal Article
LanguageEnglish
Published New York IEEE 01.09.2006
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Amplitude modulation
Architecture
Coefficients
Decision feedback equalizer (DFE)
Decision feedback equalizers
Equalizers
Feedback
Feedback loop
Filters
gigabit system
Hardware
Multiplexing
Optical fiber communication
partial pre-computation scheme
Studies
Throughput
two-stage pre-computation scheme
Upper bound
Very large scale integration
Weight reduction
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Summary:This brief addresses the design of a decision feedback equalizer (DFE) for gigabit throughput rate. It is well known that the feedback loop in a DFE limits an upper bound of the achievable speed. For a L-tap feedbackward filter (FBF) and M-pulse amplitude modulation, Parhi (1991) and Kasturia and Winters (1991) reformulated the FBF as a (M) L -to-1 multiplexer. Due to the reformulation, the overhead of extra adders and extra multiplexers are as large as (M) L . The required hardware overhead should be more severe when the DFE is implemented in parallel. In this brief, we propose two new approaches to implement the DFE when gigabit throughput rate is desired. The first approach is partial pre-computation scheme, which can trade-off between hardware complexity and computational speed. The second approach is two-stage pre-computation scheme, which can be applied to higher speed applications. In the later case, we can reduce the hardware overhead to about 2(M) (-L/2) times of [1], [2], and the iteration bound is (log 2 W+2)/(L/2+1)+(log 2 M) multiplexer-delays, where W is the wordlength of weight coefficient of a FBF. We demonstrate the proposed architectures by apply it to the 10 Gbase-LX4 optical communication systems
Bibliography:ObjectType-Article-2
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ISSN:1549-7747
1558-3791
DOI:10.1109/TCSII.2006.881165