An 88.6nW ozone pollutant sensing interface IC with a 159 dB dynamic range

Abstract

This paper presents a low power resistive sensor interface IC designed at 0.6V for ozone pollutant sensing. The large resistance range of gas sensors poses challenges in designing a low power sensor interface. Exiting architectures are insufficient for achieving a high dynamic range while enabling low VDD operation, resulting in high power consumption regardless of the adopted architecture. We present an adaptive architecture that provides baseline resistance cancellation and dynamic current control to enable low VDD operation while maintaining a dynamic range of 159dB across 20kΩ-1MΩ. The sensor interface IC is fabricated in a 65nm bulk CMOS process and consumes 88.6nW of power which is 300x lower than the state-of-art. The full system power ranges between 116 nW - 1.09 μW which includes the proposed sensor interface IC, analog to digital converter and peripheral circuits. The sensor interface's performance was verified using custom resistive metal-oxide sensors for ozone concentrations from 50 ppb to 900 ppb.