A water-immersible 2-Axis scanning mirror microsystem for ultrasound and photoacoustic microscopic imaging applications

Published

Conference Paper

For both ultrasound and photoacoustic microscopic imaging, a fast scanning ability is required, whereas the liquid environment for acoustic propagation limits the usage of traditional MEMS scanning mirrors. In this paper, a new waterimmersible scanning mirror microsystem has been designed, fabricated and tested. To achieve reliable underwater scanning, flexible polymer torsion hinges fabricated by laser micromachining were used to support the reflective silicon mirror plate. Two efficient electromagnetic microactuators consisting of compact RF choke inductors and high-strength neodymium magnet disc were constructed to drive the silicon mirror plate around a fast axis and a slow axis, respectively. The performance of the water-immersible scanning mirror microsystem in both air and water were tested using the laser tracing method. For the fast axis, the resonance frequency reached 224 Hz in air and 164 Hz in water, respectively. The scanning angles in air and water under ±10 V AC driving (at the resonance frequencies) were ±13.6° and ±10°. The scanning angles in both air and water under ±16 V DC driving were ±12°. For the slow axis, the resonance frequency reached 55 Hz in air and 38 Hz in water, respectively. The scanning angles in air and water under ±10 V AC driving (at the resonance frequencies) were ±8.5° and ±6°. The scanning angles in both air and water under ±10 V DC driving were ± 6.5°. The feasibility of using such a water-immersible scanning mirror microsystem for scanning ultrasound microscopic (SAM) imaging has been demonstrated with a 25-MHz ultrasound pulse/echo system and a target consisting of three optical fibers. © 2013 SPIE.

Full Text

Duke Authors

Cited Authors

  • Huang, CH; Yao, J; Wang, LV; Zou, J

Published Date

  • June 12, 2013

Published In

Volume / Issue

  • 8616 /

International Standard Serial Number (ISSN)

  • 0277-786X

International Standard Book Number 13 (ISBN-13)

  • 9780819493859

Digital Object Identifier (DOI)

  • 10.1117/12.2003087

Citation Source

  • Scopus