Low-power sensor applications e.g. for environmental monitoring, bio-potential recording, and wireless autonomous sensor networks require highly power-efficient ADCs, typically with resolutions of at least 10b. SAR ADCs are generally beneficial in terms of power efficiency. However, the most power-efficient designs currently lack the required accuracy for these applications [1, 2], as they are limited to 9b ENOB. Other designs that have sufficient accuracy (10b) are limited to power efficiencies above 10fJ/conv-step [3]. The aim of this work is to increase the accuracy of highly efficient SAR ADCs beyond 10b, while further improving the efficiency to 2.2fJ/conv-step. To do so, this work introduces a Data-Driven Noise-Reduction method to efficiently suppress comparator noise, applies a segmented capacitive DAC with 250aF unit elements for better efficiency and accuracy, and implements a self-oscillating comparator to locally generate the internally required oversampled clock.
[1]
Kathleen Philips,et al.
A 0.7V 7-to-10bit 0-to-2MS/s flexible SAR ADC for ultra low-power wireless sensor nodes
,
2012,
2012 Proceedings of the ESSCIRC (ESSCIRC).
[2]
Chung-Ming Huang,et al.
A 1V 11fJ/conversion-step 10bit 10MS/s asynchronous SAR ADC in 0.18µm CMOS
,
2010,
2010 Symposium on VLSI Circuits.
[3]
Eric A. M. Klumperink,et al.
A 10-bit Charge-Redistribution ADC Consuming 1.9 $\mu$W at 1 MS/s
,
2010,
IEEE Journal of Solid-State Circuits.
[4]
Hsin-Shu Chen,et al.
A 3.2fJ/c.-s. 0.35V 10b 100KS/s SAR ADC in 90nm CMOS
,
2012,
2012 Symposium on VLSI Circuits (VLSIC).