Title :
Electromechanical ΔΣ modulation with high-Q micromechanical accelerometers and pulse density modulated force feedback
Author :
Wu, Jiangfeng ; Carley, L. Richard
Author_Institution :
Dept. of Electr. & Comput. Eng., Carnegie Mellon Univ., Pittsburgh, PA, USA
Abstract :
This paper presents a comprehensive analysis of force-balanced microelectromechanical ΔΣ modulators for inertial and force sensing applications, with the emphasis on the control of high-Q micromechanical accelerometers. High Q is desirable for reducing thermal-mechanical Brownian noise but makes the control more challenging. Linear multibit force feedback using nonlinear actuators based on pulse density modulation (PDM) is described. The characteristics of the modulators, including stability, quantization noise, dynamic range, and proof-mass position error, are studied by simulations. The effects of nonidealities such as proof-mass position offset, manufacturing variations and undesired vibration modes are investigated.
Keywords :
Brownian motion; Q-factor; accelerometers; delta-sigma modulation; force feedback; microactuators; microsensors; pulse modulation; analog-to-digital conversion; electromechanical delta-sigma modulation; force sensing applications; force-balanced microelectromechanical delta-sigma modulators; high-Q micromechanical accelerometers; inertial sensing applications; linear multibit force feedback; manufacturing variations; nonlinear actuators; proof-mass position error; proof-mass position offset; pulse density modulated force feedback; pulse density modulation; quantization noise; thermal-mechanical Brownian noise; vibration modes; Accelerometers; Delta modulation; Force control; Force feedback; Hydraulic actuators; Micromechanical devices; Noise reduction; Pulse modulation; Quantization; Stability; Accelerometer; analog-to-digital (A/D) conversion; force-balanced feedback; microelectromechanical systems (MEMS);
Journal_Title :
Circuits and Systems I: Regular Papers, IEEE Transactions on
DOI :
10.1109/TCSI.2005.857084
