Power Bound Analysis of a Two-Step MASH Incremental ADC Based on Noise-Shaping SAR ADCs.

Power consumption is an important limitation in designing analog-to-digital converters (ADCs) used in low-power sensing applications. This paper estimates analytically the power bound of a two-step multi-stage noise-shaping successive-approximation-register incremental ADC (two-step MASH NS-SAR IADC) proposed in our previous work. Our model considers the impacts of thermal noise, mismatch, and CMOS process (minimum feature size in CMOS technologies) on the power bounds of the proposed IADC. The analytic results show that thermal noise and CMOS process requirements determine the power consumption lower bounds in high and low resolutions, respectively. A comparison with the most competitive single-loop delta-sigma (ΔΣ) IADC shows a 3-dB higher theoretical figure-of-merit (FoM) for our proposed IADC when the resolutions are higher than 12-bit. Our proposed systematic analysis can be used to estimate the power bounds of amplifier-based NS-SAR ADCs used in either ΔΣ or incremental mode with multi-stage and multi-step topologies designed in various CMOS technologies. The reported analytic results are confirmed by experimental results of previously reported implementations. [ABSTRACT FROM AUTHOR]