Title :
Design techniques for CMOS backplane transceivers approaching 30-Gb/s data rates
Author :
Bulzacchelli, John F.
Author_Institution :
Res. Div., T.J. Watson Res. Center, IBM, Yorktown Heights, NY, USA
Abstract :
Serial link transceivers with sophisticated equalization are needed for data transmission over high-loss electrical channels such as backplanes. This paper highlights design techniques for extending the data rates of such circuits by describing a 28-Gb/s transceiver implemented in 32-nm SOI CMOS technology. Equalization is provided by a 4-tap feed-forward equalizer (FFE) in the transmitter and a two-stage peaking amplifier with active feedback topology and 15-tap decision-feedback equalizer (DFE) in the receiver. The transmitter employs a source-series terminated (SST) driver topology with double the speed of previous designs. The use of capacitive level-shifters allows a single current-integrating summer to drive the parallel paths used for speculating the first two DFE taps. Error-free signaling at 28 Gb/s is demonstrated over a 35-dB loss channel with a power consumption of 693 mW/lane.
Keywords :
CMOS integrated circuits; decision feedback equalisers; driver circuits; feedback amplifiers; integrated circuit design; low-power electronics; network topology; silicon-on-insulator; transceivers; transmitters; CMOS backplane transceivers; SOI CMOS technology; active feedback topology; capacitive level-shifters; channel equalization; data transmission; decision-feedback equalizer; design techniques; feed-forward equalizer; loss electrical channel; power consumption; serial link transceivers; size 32 nm; source-series terminated driver topology; transmitter; two-stage peaking amplifier; Backplanes; Clocks; Decision feedback equalizers; Gain; Receivers; Transceivers; Transmitters;
Conference_Titel :
Custom Integrated Circuits Conference (CICC), 2013 IEEE
Conference_Location :
San Jose, CA
DOI :
10.1109/CICC.2013.6658405
