Title :
Fiber-coupled in-line heterodyne optical interferometer for minimally invasive sensing
Author :
Arain, Muzammil Arshad ; Riza, Nabeel A.
Author_Institution :
Photonic Inf. Process. Syst., Univ. of Central Florida, Orlando, FL, USA
Abstract :
In this paper, the first fiber-coupled no-moving-parts scanning heterodyne interferometer design using a single acoustooptic device (AOD) is reported. The design features a high-stability inline reflective architecture with free-space-scanned minimally invasive sensing via a multizone reflective sensor chip. The common path fiber interconnection allows robust remoting of the compact sensing front end. A proof-of-concept sensing experiment measuring voltage-dependent birefringence is successfully conducted using a voltage-controlled nematic liquid crystal (NLC) sensor chip. The system features a 4.69-dB optical loss, a 200-MHz output frequency, and a 1550-nm eye-safe operation wavelength. Applications for the system include any fiber-remoted sensing using the proposed free-space minimally invasive interrogating optical beams.
Keywords :
acousto-optical devices; birefringence; fibre optic sensors; heterodyne detection; light interferometers; liquid crystal devices; nematic liquid crystals; optical design techniques; optical fibre couplers; optical fibre losses; reflectivity; remote sensing; 1550 nm; 200 MHz; 4.69 dB; birefringence; common path fiber interconnection; eye-safe operation; fiber-coupled interferometer; fiber-remote sensing; free-space optical beams; heterodyne interferometer; high stability architecture; inline optical interferometer; inline reflective architecture; interrogating optical beams; minimally invasive sensing; multizone reflective sensor chip; nematic liquid crystal; no-moving-parts interferometer design; optical interferometer; optical loss; scanning interferometer design; voltage-controlled sensor chip; Acoustooptic devices; Minimally invasive surgery; Optical fiber devices; Optical fiber sensors; Optical fibers; Optical interconnections; Optical interferometry; Optical mixing; Optical sensors; Voltage; Acoustooptic devices; heterodyne optical interferometers; optical sensors; scanning interferometers;
Journal_Title :
Lightwave Technology, Journal of
DOI :
10.1109/JLT.2005.851330
