APL Photonics (Jun 2019)

Probing micron-scale distributed contortions via a twisted multicore optical fiber

  • Raja Ahmad,
  • Paul S. Westbrook,
  • Wing Ko,
  • Kenneth S. Feder

DOI
https://doi.org/10.1063/1.5098959
Journal volume & issue
Vol. 4, no. 6
pp. 066101 – 066101-7

Abstract

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Continuous measurement of small length scale contortions along an arbitrary path is a highly relevant goal within many branches of engineering and technology. An optical fiber—where the probing light propagates within a confined and shielded region—presents an ideal platform for developing the distributed contortion-sensors. In the past, significant progress has been made in developing optical fiber sensors, but a robust and high-resolution distributed contortion-sensor has not been reported in detail. Here, we report the first distributed measurements of fiber contortions with an ultrahigh sensitivity—≤0.3 μm in the transverse plane, 40 μm longitudinal spatial step size, and ≤8 μm resolution for periodic contortions in the longitudinal plane—via a Bragg-grating-inscribed twisted multicore optical fiber. The results are in excellent agreement with the predictions from the Euler-Bernoulli beam-bending model that relates the applied force with the fiber microcontortions. Our distributed-sensor holds promise for a widespread application within a diverse range of fields including biotechnology, robotics, transportation, geology, and security.