High-speed backplane receivers based on front-end ADCs with digital equalization facilitate design reuse, portability, and flexibility to reconfigure itself and accommodate different channel environments. However, power and complexity of such receivers can be high and require thorough high-level exploration to optimize design tradeoffs. This paper presents a backplane receiver model consisting of a simple, accurate, experimentally-verified, and parameterized high-speed flash ADC and a configurable digital equalizer for design-space exploration. Simulations demonstrate tradeoffs between ADC and equalizer bit resolution while maintaining constant receiver performance.

This paper presents a 12.5-Gbps transmitter that uses a lookup table (LUT)-based equalizer to compensate for within-die imperfections. An equalization technique with 2x sampling is proposed to accommodate timing offsets in the multiphase clocks used for 8:1 serialization. LUT code remapping is also demonstrated to compensate for mismatch effects that introduce nonlinearity in the transmit DAC. Experimental results of a 7-bit resolution transmitter with 4-tap equalization, implemented in 0.13 mum CMOS, show the LUT-based equalizer can significantly improve the signal integrity of an otherwise closed eye for data transmitted at 12.5-Gbps.