A 12.3mW 12.5Gb/s complete transceiver in 65nm CMOS

Koji Fukuda, H. Yamashita, G. Ono, R. Nemoto, Eiichi Suzuki, T. Takemoto, F. Yuki, T. Saito
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引用次数: 42

Abstract

For the people involved with multi-Gb/s chip-to-chip serial links, reducing power dissipation per Gb/s to less than 1mW/(Gb/s) (i.e., 1pJ/b) has been a long-held goal. Several years ago, the power dissipation of these links was in the range of about 10 to 20mW/(Gb/s). In 2007, Poulton et al. developed a 14mW 6.25Gb/s transceiver with power efficiency of 2.2mW/(Gb/s) [1]. Thereafter, there were some efforts aiming to reduce power of each building block in a transceiver [2, 3]. This paper presents a 12.3mW 12.5Gb/s complete transceiver (including CDR, MUX/DEMUX, and global clock distribution)in 65nm CMOS with power efficiency of 0.98mW/(Gb/s). To achieve low power, a resonant-clock distribution with distributed on-chip inductors and a low-swing voltage-mode driver with pulse-current boosting are used in the transmitter, while a symbol-rate comparator/phase detector using 4-stage sense amplifier and phase-rotating PLL with variable delay are used in the receiver.
一个采用65nm CMOS的12.3mW 12.5Gb/s完整收发器
对于涉及多Gb/s芯片对芯片串行链路的人来说,将每Gb/s的功耗降低到低于1mW/(Gb/s)(即1pJ/b)一直是一个长期的目标。几年前,这些链路的功耗大约在10到20mW/(Gb/s)之间。2007年,Poulton等人开发了14mW 6.25Gb/s的收发器,功率效率为2.2mW/(Gb/s)[1]。此后,有一些努力旨在降低收发器中每个构建模块的功率[2,3]。本文提出了一种功率效率为0.98mW/(Gb/s)的基于65nm CMOS的12.3mW 12.5Gb/s完整收发器(包括CDR、MUX/DEMUX和全局时钟分布)。为了实现低功耗,发射机采用了带有分布式片上电感的谐振时钟分布和带有脉冲电流增强的低摆幅电压模式驱动器,而接收机采用了带有4级感测放大器的符号速率比较器/鉴相器和可变延迟的相位旋转锁相环。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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