The implementation of an unclocked DFE (UC-DFE) architecture for high-speed PAM-4 signals is investigated in this brief. Instead of clocked slicers and flip-flops, data-decision and feedback delay control are performed by saturated analog delay chains. As a result, the UC-DFE, previously exploited for NRZ signals, saves power consumption and silicon area while the simple implementation allows operation at high data-rate. A receiver front-end comprising a linear equalizer and the proposed 2-tap UC-DFE scheme is designed in 7 nm FinFET technology. From post-layout simulations, the receiver recovers a PAM-4 signal at 112 Gb/s after an 18 dB loss channel with a power efficiency of 0.47 pJ/bit. The receiver also works with NRZ signals at half the bit-rate equalizing 24 dB channel loss with a power efficiency of 0.70 pJ/bit.
A 112 Gb/s PAM-4 RX Front-End with Unclocked Decision Feedback Equalizer
Petricli I.;Zhang H.;Monaco E.;Mazzanti A.
2021-01-01
Abstract
The implementation of an unclocked DFE (UC-DFE) architecture for high-speed PAM-4 signals is investigated in this brief. Instead of clocked slicers and flip-flops, data-decision and feedback delay control are performed by saturated analog delay chains. As a result, the UC-DFE, previously exploited for NRZ signals, saves power consumption and silicon area while the simple implementation allows operation at high data-rate. A receiver front-end comprising a linear equalizer and the proposed 2-tap UC-DFE scheme is designed in 7 nm FinFET technology. From post-layout simulations, the receiver recovers a PAM-4 signal at 112 Gb/s after an 18 dB loss channel with a power efficiency of 0.47 pJ/bit. The receiver also works with NRZ signals at half the bit-rate equalizing 24 dB channel loss with a power efficiency of 0.70 pJ/bit.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
