A 50μW biasing feedback loop with 6ms settling time for a MEMS microphone with digital output

Author

van den Boom, J.

Author_Institution

NXP Semicond., Nijmegen, Netherlands

fYear

2012

Firstpage

200

Lastpage

202

Abstract

A MEMS microphone is a variable capacitor where the distance d between the compliant membrane and the rigid backplate is proportional to the air (acoustic) pressure. If the charge Q at the plates remains constant, there is a linear relationship between the voltage across the plates and the distance given by: ΔV=Q×Δd/εA. A practical charge source implementation (Fig. 11.3.1) is a DC-DC converter (V_d) with a very high series resistance in the form of bipolar diodes (D_{1, 2}) [1]. A capacitor (C_g) provides the signal ground for the microphone (C_mems). An ADC performs continuous-time voltage readout of the microphone signal pin. Preferably its DC bias is equal to the ADC common-mode voltage. This paper deals with a biasing feedback loop (BFL) that realizes this function.

Keywords

DC-DC power convertors; analogue-digital conversion; capacitors; circuit feedback; micromechanical devices; microphones; ADC; DC bias; DC-DC converter; MEMS microphone; air pressure; biasing feedback loop; bipolar diodes; charge source implementation; common-mode voltage; continuous-time voltage readout; digital output; microphone signal pin; power 50 muW; rigid backplate; series resistance; settling time; time 6 ms; variable capacitor; CMOS integrated circuits; Capacitors; Charge pumps; Micromechanical devices; Microphones; Noise; Switches;

fLanguage

English

Publisher

ieee

Conference_Titel

Solid-State Circuits Conference Digest of Technical Papers (ISSCC), 2012 IEEE International

Conference_Location

San Francisco, CA

ISSN

0193-6530

Print_ISBN

978-1-4673-0376-7

Type

conf

DOI

10.1109/ISSCC.2012.6176974

Filename

6176974