An offset-compensated switched-capacitor interface circuit for closed-loop MEMS capacitive accelerometer

“…Force-feedback approach has been commonly used to minimize the impact of mechanical imperfections and inherent non-linearities in MEMS capacitive sensors through close-loop bias voltage tuning [14,23]. A feedback loop can be successfully exploited for offset cancellation and the dynamic range enhancement [24][25]. The reset noise reduction schemes [26] also include a feedback loop that either cancels the reset noise or reduces the bandwidth of noise or controls the reset process itself.…”

“…Therefore, main advantages include broad dynamic range, low power consumption and robustness against the environmental noise. However, the vast majority of realizations do not meet the readout circuit requirements for MEMS microphones [22][23][24][25][26][27].…”

Design of CMOS readout frontend circuit for MEMS capacitive microphones

“…Force-feedback approach has been commonly used to minimize the impact of mechanical imperfections and inherent non-linearities in MEMS capacitive sensors through close-loop bias voltage tuning [14,23]. A feedback loop can be successfully exploited for offset cancellation and the dynamic range enhancement [24][25]. The reset noise reduction schemes [26] also include a feedback loop that either cancels the reset noise or reduces the bandwidth of noise or controls the reset process itself.…”

“…Therefore, main advantages include broad dynamic range, low power consumption and robustness against the environmental noise. However, the vast majority of realizations do not meet the readout circuit requirements for MEMS microphones [22][23][24][25][26][27].…”

Design of CMOS readout frontend circuit for MEMS capacitive microphones

Circuit considerations and design for MEMS capacitance measurements