A low-power interface for readout and motion-control of a MEMS capacitive sensor is presented. The interface consists of a hybrid third-order sigma-delta modulator. The interface enhances the linearity and stability of the sensor by applying force feedback through bias voltage modulation. The modulator employs a hybrid, continuous + discrete-time topology, to reduce power consumption by avoiding a separate pre-amplifier for the sensor. Power consumption in the modulator is further reduced by an op-amp sharing scheme. The interface is designed in 0.35 um CMOS technology and is simulated in Cadence-Spectre. Simulation results are shown for a MEMS capacitive microphone
Recent years have witnessed an improvement in the energy efficiency of capacitive sensor interfaces ...
This thesis focuses on the design of integrated readout circuits for differential capacitive sensing...
In this paper we present a readout circuit for capacitive micro-electro-mechanical system (MEMS) sen...
This paper presents a low-power CMOS interface for a MEMS capacitive sensor. The interface has embed...
A CMOS interface for a piston-type MEMS capacitive microphone is presented. It performs a capacitanc...
This paper presents a low power, compact, and low-complexity pulse-width modulation-based interface ...
The feasibility of a force-balance interface based on a second-order delta-sigma (/spl Delta//spl Si...
Abstract—This papers presents a front-end circuit for inter-facing to differential capacitive sensor...
This dissertation demonstrates the feasibility of three novel low-power and low-noise schemes for th...
AbstractCapacitive sensors have different configurations depending on their fabrication; some sensor...
This paper discusses the importance and the issues of interfacing capacitive sensors. Two architectu...
In recent years, the demand for low-cost, high performance, and miniature sized MEMS capacitive iner...
Since large scientific and economic interests reside in micro-electromechanical systems (MEMS), this...
Nowadays, due to advancement of micro fabrication technology, Micro-Electro-Mechanical-Systems (MEMS...
The development of microelectromechanical system (MEMS) processes enables the integration of capacit...
Recent years have witnessed an improvement in the energy efficiency of capacitive sensor interfaces ...
This thesis focuses on the design of integrated readout circuits for differential capacitive sensing...
In this paper we present a readout circuit for capacitive micro-electro-mechanical system (MEMS) sen...
This paper presents a low-power CMOS interface for a MEMS capacitive sensor. The interface has embed...
A CMOS interface for a piston-type MEMS capacitive microphone is presented. It performs a capacitanc...
This paper presents a low power, compact, and low-complexity pulse-width modulation-based interface ...
The feasibility of a force-balance interface based on a second-order delta-sigma (/spl Delta//spl Si...
Abstract—This papers presents a front-end circuit for inter-facing to differential capacitive sensor...
This dissertation demonstrates the feasibility of three novel low-power and low-noise schemes for th...
AbstractCapacitive sensors have different configurations depending on their fabrication; some sensor...
This paper discusses the importance and the issues of interfacing capacitive sensors. Two architectu...
In recent years, the demand for low-cost, high performance, and miniature sized MEMS capacitive iner...
Since large scientific and economic interests reside in micro-electromechanical systems (MEMS), this...
Nowadays, due to advancement of micro fabrication technology, Micro-Electro-Mechanical-Systems (MEMS...
The development of microelectromechanical system (MEMS) processes enables the integration of capacit...
Recent years have witnessed an improvement in the energy efficiency of capacitive sensor interfaces ...
This thesis focuses on the design of integrated readout circuits for differential capacitive sensing...
In this paper we present a readout circuit for capacitive micro-electro-mechanical system (MEMS) sen...