采用90nm CMOS技术的20Gb/s 40mW均衡器

S. Ibrahim, B. Razavi
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引用次数: 16

摘要

为了减少芯片的引脚数和减少印刷电路板和背板上布线的复杂性,用少量串行链路代替大量并行通道是可取的。这种转换还可以潜在地节省大量功率,因为它减少了输出驱动器的数量,同时保持I/O电压波动和终端阻抗相对恒定。因此,在不久的将来,接近20gb /s的数据速率将变得普遍。在这些速度下,FR4板的损耗带来了巨大的挑战,需要大量的均衡。从电路设计的角度来看,采用线性均衡(在发射器和接收器中)更简单,但从系统设计的角度来看,两个严重的问题使这种方法没有吸引力:串扰放大和缺乏对阻抗不连续(通道频率响应中的尖锐陷波)进行均衡的能力。在一个最佳的、实用的系统中,人们可以在发射器中放置4到5 dB的线性均衡,在接收器中放置相似的量,并通过决策反馈均衡器(DFE)执行剩余的均衡,从而缓解这两个问题。
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A 20Gb/s 40mW equalizer in 90nm CMOS technology
In order to reduce the pin count of chips and the complexity of the routing on printed-circuit boards and backplanes, it is desirable to replace a large number of parallel channels with a few serial links. Such a transformation can also potentially save significant power because it lowers the number of output drivers while maintaining the I/O voltage swings and termination impedances relatively constant. It is therefore plausible that data rates approaching 20 Gb/s will become common in the near future. At these speeds, the loss of FR4 boards poses a great challenge, requiring heavy equalization. From circuit design point of view, it is simpler to employ linear equalization (in the transmitter and the receiver), but from system design point of view, two serious issues make this approach unattractive: the amplification of crosstalk and the lack of ability to equalize for impedance discontinuities (sharp notches in the channel frequency response). In an optimum, yet practical system, one would place 4 to 5 dB of linear equalization in the transmitter and a similar amount in the receiver, and perform the remaining equalization by means of a decision-feedback equalizer (DFE), thus alleviating both issues.
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