Summary
In this paper a low power CMOS potentiostat is presented for energy limited applications such as human implantable sensors. The main focus is on using different techniques to reduce the power consumption at different circuit blocks, especially in the output stage that delivers power to the electrochemical cell. The proposed technique includes the use of a class D amplifier to reduce conduction power dissipation compared with conventional linear methods. Power dissipation has been improved by several other considerations such as elimination of opamp blocks which consume static power, avoiding current sampling stages and using dynamic latched comparators for loop error calculations. Closed loop stability problem and a low power solution to overcome this issue are addressed in the paper. The role of effective parameters such as inductor value, output MOSFET dimensions and clock pulse timing has been investigated and optimization considerations are used to achieve the low power potentiostat. Evaluation results show that a 12.96‐μW potentiostat with 1.03‐μW power dissipation and 89% efficiency is achievable with a linearity of R2 = 0.998. Copyright © 2016 John Wiley & Sons, Ltd.