Bio-inspired fluidic thermal angular accelerometer

Hommood Alrowais; Patrick Getz; Min‐gu Kim; Jin-Jyh Su; Oliver Brand

doi:10.1109/memsys.2016.7421740

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JOURNAL ARTICLE

Bio-inspired fluidic thermal angular accelerometer

Hommood Alrowais Patrick Getz Min‐gu Kim Jin-Jyh Su Oliver Brand

Year: 2016 Vol: 115 Pages: 761-764

DOI: 10.1109/memsys.2016.7421740

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Abstract

This paper reports on a bio-inspired angular accelerometer based on a two-mask microfluidic process using a PDMS mold. The sensor is inspired by the semicircular canals in mammalian vestibular systems and pairs a fluid-filled microtorus with a thermal detection principle based on thermal convection. With inherent linear acceleration insensitivity, the sensor features a sensitivity of 29.8μV/deg/s ² =1.7mV/rad/s ² , a dynamic range of 14,000deg/s ² and a detection limit of ~20deg/s ² .

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Accelerometer Physics

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Advanced MEMS and NEMS Technologies

Physical Sciences → Engineering → Electrical and Electronic Engineering

Mechanical and Optical Resonators

Physical Sciences → Physics and Astronomy → Atomic and Molecular Physics, and Optics

Geophysics and Sensor Technology

Physical Sciences → Engineering → Ocean Engineering

Bio-inspired fluidic thermal angular accelerometer

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