The Design and Simulation of a Coarse-to-Fine Optical MEMS Accelerometer

TL;DR

This paper introduces a novel optical MEMS accelerometer with a coarse-to-fine measurement approach, significantly enhancing sensitivity and linear range while reducing cross-axis sensitivity, based on a dual-wavelength Fabry Perot interferometer design.

Contribution

The paper presents a new coarse-to-fine optical MEMS accelerometer design with dual-wavelength FP cavities, achieving higher sensitivity and reduced cross-axis sensitivity compared to existing devices.

Findings

Optical sensitivity is 8 nm/g.

Mechanical sensitivity is 190 nm/g.

Linear measurement range is 5 g.

Abstract

In this paper, a novel coarse-to-fine optical MEMS accelerometer based on the Fabry Perot (FP) interferometer is proposed. The mechanical structure consists of a proof mass that is suspended by four L-shaped springs. The deflection of the proof mass due to the applied acceleration is detected using two FP cavities which comprise the optical system of the device. Using coarse-to-fine measurement and the dual-wavelength method increases the sensitivity of the accelerometer as well as the linear measurement range simultaneously. The optical simulation shows that the sensitivity of the proposed device is 10 times as high as that of a similar optical MEMS accelerometer with one FP cavity. In addition, the proposed optical system is insensitive to the displacements of the proof mass in orthogonal directions as a result of which cross-axis sensitivity is considerably reduced. The minimum feature size of the structure is 15 um and the optical signal is conducted completely through the optical fibers, facilitating the fabrication of the device. The simulation results are as follows: mechanical sensitivity of 190 nm/g, optical sensitivity of 8 nm/g, linear measurement of 5 g, and first resonance frequency of 1141 Hz.