Title :
A Scalable 5–15 Gbps, 14–75 mW Low-Power I/O Transceiver in 65 nm CMOS
Author :
Balamurugan, Ganesh ; Kennedy, Joseph ; Banerjee, Gaurab ; Jaussi, James E. ; Mansuri, Mozhgan ; Mahony, Frank O. ; Casper, Bryan ; Mooney, Randy
Author_Institution :
Intel Corp., Hillsboro
fDate :
4/1/2008 12:00:00 AM
Abstract :
We present a scalable low-power I/O transceiver in 65 nm CMOS, capable of 5-15 Gbps operation over single-board and backplane FR4 channels with power efficiencies between 2.8-6.5 mW/Gbps. Nonlinear power-performance tradeoff is achieved by the use of scalable transceiver circuit blocks and joint optimization of the supply voltage, bias currents and driver power with data rate. Low-power operation is enabled by passive equalization through inductive link termination, active continuous-time RX equalization, global TX/RX clock distribution with on-die transmission lines, and low-noise offset-calibrated receivers.
Keywords :
CMOS integrated circuits; low-power electronics; radio receivers; telecommunication channels; transceivers; transmission lines; CMOS; TX/RX clock distribution; active continuous-time RX equalization; backplane FR4 channel; bias currents; driver power; inductive link termination; low-noise offset-calibrated receiver; nonlinear power-performance tradeoff; on-die transmission lines; passive equalization; power 14 mW to 75 mW; scalable low-power I/O transceiver; scalable transceiver circuit; single-board channel; size 65 nm; supply voltage; Backplanes; Bandwidth; Clocks; Driver circuits; Energy management; Microprocessors; Power dissipation; Power system management; Transceivers; Voltage; Electrical signaling; I/O power optimization; high-speed I/O; inductive termination; low-power I/O; low-power equalization; passive clock distribution; power-efficient links; scalable circuits;
Journal_Title :
Solid-State Circuits, IEEE Journal of
DOI :
10.1109/JSSC.2008.917522
