1.2V CMOS乘法器，可实现10gbit /s均衡

Proceedings of the 31st European Solid-State Circuits Conference, 2005. ESSCIRC 2005. Pub Date : 2005-12-05 DOI:10.1109/ESSCIR.2005.1541639

Justin P. Abbott, C. Plett, J. Rogers

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引用次数: 3

摘要

本文介绍了用于10gbit /s连续时间FIR滤波器的低功耗1.2V CMOS乘法器的设计。乘法器可以在不使用数模转换器的情况下进行数字控制，并具有从-1到+ 1的32种可能的增益设置。为了获得负增益，在乘法器的输入端使用反相开关，将求和节点的负载减少50%。由于带宽瓶颈发生在求和节点，这允许更高频率的操作或增加每个求和节点的乘数。增益误差小于2%，线性误差小于3.3%，功耗为1.5mW。

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A 1.2V CMOS multiplier for 10 Gbit/s equalization

This paper describes the design of a low power 1.2V CMOS multiplier for a 10 Gbit/s continuous time FIR filter. The multiplier can be digitally controlled without the use of a Digital to Analog Converter and has 32 possible gain settings from -1 to + 1. To achieve negative gain an inverting switch is used at the input of the multiplier, reducing loading at the summing node by 50%. As the bandwidth bottle neck occurs at the summing node, this allows for higher frequency operation or an increase in the number of multipliers per summing node. The gain errors are less than 2%, linearity errors are less than 3.3%, and the power consumption is 1.5mW.

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Proceedings of the 31st European Solid-State Circuits Conference, 2005. ESSCIRC 2005.

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