A 16Gb/s 1st-Tap FFE and 3-Tap DFE in 90nm CMOS

H. Sugita, K. Sunaga, Koichi Yamaguchi, M. Mizuno
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引用次数: 17

Abstract

Much effort has been made toward producing a high-speed multi-tap decision feedback equalizer (DFE), which would be a key component in removing inter-symbol interference (ISI) in high-speed chip-to-chip communication. A loop-unrolled approach is widely used in work toward the design of high-speed multi-tap DFEs. It eliminates the feedback operation in first post-cursor equalization [1–3], an operation that limits operational speed in conventional multi-tap DFEs. There are two problems, however, to its application to equalization of 16Gb/s signals. The first is that additional components in the feedback path, used for speculation on the basis of sampled data, increase 2nd-tap feedback delay, preventing high-speed operations. The second problem is that jitter increase in equalized waveforms prevents accurate clock timing recovery because the 1st tap ISI of the waveform is left un-equalized. In response to this situation, we have developed three techniques for achieving 16Gb/s communication: (1) an analog feedforward technique for high-speed 1st-tap ISI equalization, (2) an analog feedforward technique for jitter reduction in equalized edges, and (3) technique for employing bypass feedback and a voltage swing limiter in order to speed-up both 2ndtap and 3rd-tap equalization. We have applied these techniques to a 16Gb/s equalizer fabricated in a 90nm CMOS process, and their use helps achieve a 33% increase in operating speed over that with conventional multi-tap DFEs[3].
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90nm CMOS 16Gb/s 1 - tap FFE和3-Tap DFE
高速多抽头决策反馈均衡器(DFE)是高速片对片通信中消除符号间干扰(ISI)的关键部件,目前已经在这方面做出了很多努力。在高速多抽头dfe的设计工作中,广泛采用环展开方法。它消除了第一次后光标均衡中的反馈操作[1-3],这种操作限制了传统多点dfe的操作速度。然而,将其应用于16Gb/s信号的均衡有两个问题。首先是反馈路径中的附加组件,用于基于采样数据的推测,增加了二次抽头反馈延迟,阻碍了高速操作。第二个问题是,抖动增加均衡波形阻止准确的时钟时序恢复,因为波形的第一个抽头ISI是不均衡的。针对这种情况,我们开发了三种实现16Gb/s通信的技术:(1)用于高速第一抽头ISI均衡的模拟前馈技术,(2)用于均衡边缘抖动减少的模拟前馈技术,以及(3)用于使用旁路反馈和电压摆幅限制器以加速第二抽头和第三抽头均衡的技术。我们已经将这些技术应用于用90nm CMOS工艺制造的16Gb/s均衡器,它们的使用有助于实现比传统多抽头dfe提高33%的操作速度[3]。
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