Title :
A Self-Duty-Cycled and Synchronized UWB Pulse-Radio Receiver SoC With Automatic Threshold-Recovery Based Demodulation
Author :
Vigraham, Baradwaj ; Kinget, Peter R.
Author_Institution :
Columbia Univ., New York, NY, USA
Abstract :
A fully self-duty-cycled and synchronized UWB pulse-radio receiver SoC targeted at low-data-rate communication is presented. The receiver uses pulse-radio UWB in the 3.6-5 GHz band to achieve a high energy efficiency. The proposed architecture employs a a demodulator with an automatic analog threshold-recovery and an all-digital clock-and-data-recovery synchronizer. The SoC synchronizes with the incoming pulse stream from the transmitter and duty-cycles itself. The SoC prototype achieves a -79.5 dBm, 1 Mbps-normalized sensitivity for a mere 375 pJ/bit of power consumption in 65 nm LP CMOS, with aggressive duty-cycling ( ≈30 ns ON times) combined with bias circuit duty-cycling. The SoC is fully integrated to achieve RF-in to bit-out operation and can interface with off-chip, low speed digital components.
Keywords :
CMOS integrated circuits; clock and data recovery circuits; demodulators; low-power electronics; radio receivers; synchronisation; system-on-chip; ultra wideband communication; LP CMOS; RF-in to bit-out operation; all-digital clock-and-data-recovery synchronizer; automatic analog threshold-recovery; bias circuit duty-cycling; demodulator; frequency 3.6 GHz to 5 GHz; low-data-rate communication; pulse stream; self-duty-cycled UWB pulse-radio receiver SoC; synchronized UWB pulse-radio receiver SoC; Clocks; Demodulation; Inductance; Logic gates; Radio frequency; Receivers; Synchronization; Automatic threshold recovery; IR-UWB; PR-UWB; duty-cycling; impulse-radio receiver; low power; multipath; self-duty-cycling; synchronization;
Journal_Title :
Solid-State Circuits, IEEE Journal of
DOI :
10.1109/JSSC.2014.2303804
