A 6.8mW 7.4Gb/s clock-forwarded receiver with up to 300MHz jitter tracking in 65nm CMOS

Masum Hossain, A. C. Carusone
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引用次数: 18

Abstract

High density multilink interfaces such as QPI and HyperTransport include a dedicated link to carry a synchronous clock from the transmitter to receiver and shared by 5 – 20 data transceivers. Sub-rate clocks ameliorate jitter amplification in lossy channels. The forwarded clock must be frequency-multiplied and aligned with the data at each receiver. Per pin deskewing is done at startup [1]; the optimum deskew setting is stored and the calibration circuitry turned off during normal operation. Jitter on the forwarded clock is correlated with jitter on the data because both are generated by the same transmitter. Hence, jitter tolerance is improved by retiming the data with a clock that tracks correlated jitter on the forwarded clock [2]. However, since the delay of the data and clock paths typically differ by several UI, very high frequency jitter will appear out-of-phase at the receiver and should not be tracked. For a delay mismatch of L UI between clock and data, jitter tolerance is improved by tracking jitter up to fbit /4L [2]. If the mismatch is 5UI, at 4Gb/s and 8Gb/s the clock path jitter tracking bandwidth (JTB) should be 200MHz and 400MHz respectively. In summary, the clock path in a clock forwarded transceiver should provide flexible clock multiplication, a controlled phase shift, and a JTB adjustable over 100's of MHz to accommodate different channel losses, bit rates, and path delay mismatches.
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一个6.8mW 7.4Gb/s时钟转发接收器,在65nm CMOS中具有高达300MHz的抖动跟踪
高密度多链路接口,如QPI和HyperTransport,包括一条专用链路,将同步时钟从发送端传送到接收端,并由5 - 20个数据收发器共享。子速率时钟改善了有损信道中的抖动放大。转发的时钟必须乘以频率,并与每个接收器的数据保持一致。每针倾斜在启动时完成[1];最佳的桌面设置存储和校准电路关闭在正常操作期间。转发时钟上的抖动与数据上的抖动是相关的,因为两者都是由同一发射机产生的。因此,通过使用跟踪转发时钟上相关抖动的时钟对数据进行重定时,可以提高抖动容忍度[2]。然而,由于数据和时钟路径的延迟通常相差几个UI,因此接收器将出现高频抖动,不应跟踪。对于时钟和数据之间的L UI延迟不匹配,通过跟踪高达fbit /4L的抖动来提高抖动容忍度[2]。如果不匹配是5UI,在4Gb/s和8Gb/s时,时钟路径抖动跟踪带宽(JTB)应该分别为200MHz和400MHz。总之,时钟转发收发器中的时钟路径应该提供灵活的时钟倍增、可控的相移和100 MHz以上可调的JTB,以适应不同的信道损耗、比特率和路径延迟不匹配。
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