Title :
Design and Characterization of Artificial Haircell Sensor for Flow Sensing With Ultrahigh Velocity and Angular Sensitivity
Author :
Chen, Nannan ; Tucker, Craig ; Engel, Jonathan M. ; Yang, Yingchen ; Pandya, Saunvit ; Liu, Chang
Author_Institution :
Univ. of Illinois, Urbana-Champaign
Abstract :
We report the development of an artificial hair cell (AHC) sensor with design inspired by biological hair cells. The sensor consists of a silicon cantilever beam with a high-aspect-ratio cilium attached at the distal end. Sensing is based on silicon piezoresistive strain gauge at the base of the cantilever. The cilium is made of photodefinable SU-8 epoxy and can be up to 700-mum tall. In this paper, we focus on flow-sensing applications. We have characterized the performance of the AHC sensor both in water and in air. For underwater applications, we have characterized the sensor under two flow conditions: steady-state laminar flow (dc flow) and oscillatory flow (ac flow). The detection limit of the sensor under ac flow in water is experimentally established to be below 1 mm/s. A best case angular resolution of 2.16deg is also achieved for the sensor´s yaw response in air.
Keywords :
biomechanics; cantilevers; flow sensors; micromechanical devices; piezoresistive devices; ac flow; angular sensitivity; artificial hair cell sensor; biological hair cells; biomechanics; dc flow; flow sensing; high-aspect-ratio cilium; microelectromechanical devices; oscillatory flow; photodefinable SU-8 epoxy; piezoresistive devices; sensory aids; silicon cantilever beam; silicon piezoresistive strain gauge; steady-state laminar flow; ultrahigh velocity; underwater application; Biosensors; Ear; Hair; Image sensors; Insects; Marine animals; Micromechanical devices; Sensor arrays; Sensor phenomena and characterization; Silicon; Biomechanics; microelectromechanical devices; piezoresistive devices; sensitivity; sensory aids; silicon;
Journal_Title :
Microelectromechanical Systems, Journal of
DOI :
10.1109/JMEMS.2007.902436
