Title :
An 8–16 Gb/s, 0.65–1.05 pJ/b, Voltage-Mode Transmitter With Analog Impedance Modulation Equalization and Sub-3 ns Power-State Transitioning
Author :
Young-Hoon Song ; Hae-Woong Yang ; Hao Li ; Chiang, Patrick Yin ; Palermo, Samuel
Author_Institution :
Electr. Eng. Dept., Texas A&M Univ., College Station, TX, USA
Abstract :
Serial link transmitters which efficiently incorporate equalization, while also enabling fast power-state transitioning to leverage dynamic power scaling, are necessary to meet future systems´ I/O requirements. This paper presents a scalable voltage-mode transmitter which offers low static power dissipation and adopts an impedance-modulated 2-tap equalizer with analog tap control, thereby obviating driver segmentation and reducing pre-driver complexity and dynamic power. Topologies that allow for rapid power-up/down, including a replica-biased voltage regulator to power the output stages of multiple transmit channels and per-channel quadrature clock generation with injection-locked oscillators (ILO), enable fast power-state transitioning. Energy efficiency is further improved with capacitively driven low-swing global clock distribution and supply scaling at lower data rates, while output eye quality is maintained at low voltages with automatic phase calibration of the local ILO-generated quarter-rate clocks. A prototype fabricated in a general purpose 65 nm CMOS process includes a 2 mm global clock distribution network and two transmitters that support an output swing range of 100-300 mV with up to 12 dB of equalization. The transmitters achieve 8-16 Gb/s operation at 0.65-1.05 pJ/b energy efficiency and sub-3 ns power-up/down times.
Keywords :
CMOS analogue integrated circuits; clock distribution networks; driver circuits; equalisers; injection locked oscillators; transmitters; voltage regulators; CMOS process; analog impedance modulation equalization; analog tap control; automatic phase calibration; bit rate 8 Gbit/s to 16 Gbit/s; capacitively driven low-swing global clock distribution; data rates; driver segmentation; dynamic power scaling; energy efficiency; equalization; global clock distribution network; impedance-modulated 2-tap equalizer; injection-locked oscillators; local ILO-generated quarter-rate clocks; low static power dissipation; multiple transmit channels; output eye quality; per-channel quadrature clock generation; power-state transitioning; pre-driver complexity reduction; replica-biased voltage regulator; scalable voltage-mode transmitter; serial link transmitters; size 65 nm; system I/O requirements; voltage 100 mV to 300 mV; CMOS integrated circuits; Clocks; Equalizers; Impedance; Transmitters; Voltage control; Wires; Capacitance; high-speed I/O; injection-locked oscillator; low-power; power management; timing error calibration; transmit equalization; voltage-mode driver;
Journal_Title :
Solid-State Circuits, IEEE Journal of
DOI :
10.1109/JSSC.2014.2353795
