论文信息 - A low-power 28 Gb/s CDR using artificial lc transmission line technique in 65 nm CMOS

A low-power 28 Gb/s CDR using artificial lc transmission line technique in 65 nm CMOS

This paper presents a low-power 28 Gb/s PLL-based clock and data recovery circuit in 65 nm CMOS technology. The artificial LC transmission line technique is proposed to be used in the full-rate bang-bang phase detector to reduce the number of D-latches and save power consumption by 42.8% compared with the conventional phase detector design. By using the transmission line technique, the retiming circuit is merged into the phase detector, which further saves power of the data retiming circuit. The compact phase detector with built-in retiming circuit also alleviates the capacitive loading of and saves corresponding power consumed by the clock buffer. In addition, the artificial LC transmission line is proposed to be used in the clock buffer to drive the distributed capacitive loads presented by separate D-latch and save power consumption by 50% compared with the conventional inductive peaking clock buffer. The total power consumption of the CDR is 35 mW from a 1.1 V supply.

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