Superstructured fiber-optic contact force sensor with minimal cosensitivity to temperature and axial strain

Christopher R. Dennison; Peter M. Wild

doi:10.1364/AO.51.001188

Applied Optics
Vol. 51,
Issue 9,
pp. 1188-1197
(2012)
•https://doi.org/10.1364/AO.51.001188

Superstructured fiber-optic contact force sensor with minimal cosensitivity to temperature and axial strain

Christopher R. Dennison and Peter M. Wild

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Christopher R. Dennison and Peter M. Wild, "Superstructured fiber-optic contact force sensor with minimal cosensitivity to temperature and axial strain," Appl. Opt. 51, 1188-1197 (2012)

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Table of Contents Category
- Fiber Optics and Optical Communications
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About this Article
History
- Original Manuscript: September 7, 2011
- Revised Manuscript: December 7, 2011
- Manuscript Accepted: December 9, 2011
- Published: March 12, 2012

Abstract

In this work a new superstructured, in-fiber Bragg grating (FBG)-based, contact force sensor is presented that is based on birefringent D-shape optical fiber. The sensor superstructure comprises a polyimide sheath, a stress-concentrating feature, and an alignment feature that repeatably orients the sensor with respect to contact forces. A combination of plane elasticity and strain-optic models is used to predict sensor performance in terms of sensitivity to contact force and axial strain. Model predictions are validated through experimental calibration and indicate contact force, axial strain, and temperature sensitivities of $169.6 pm / (N / mm)$ , $0.01 pm / μ ε$ , and $- 1.12 pm / ° C$ in terms of spectral separation. The sensor addresses challenges associated with contact force sensors that are based on FBGs in birefringent fiber, FBGs in conventional optical fiber, and tilted FBGs. Relative to other birefringent fiber sensors, the sensor has contact force sensitivity comparable to the highest sensitivity of commercially available birefringent fibers and, unlike other birefringent fiber sensors, is self-aligning with respect to contact forces. Unlike sensors based on Bragg gratings in conventional fiber and tilted Bragg gratings, the sensor has minimal cosensitivity to both axial strain and changes in temperature.

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Calibration protocol	Measurand Unit	Trial	Sensitivity (pm/measurand unit)
Calibration protocol	Measurand Unit	Trial	Slow Axis	$r^{2}$ b	Fast Axis	$r^{2}$ b	Spectral Separation
Contact force, without alignment feature	( $N / mm$ )	1	$255.9 \pm 21.1$	0.96	$61.7 \pm 8.00$	0.91	194.2
Contact force, with alignment feature	( $N / mm$ )	1	$228.6 \pm 4.0$	0.99	$62.4 \pm 3.7$	0.98	166.2
		2	$232.1 \pm 4.3$	0.99	$62.5 \pm 4.1$	0.98	169.6
		3	$234.3 \pm 4.1$	0.99	$61.6 \pm 5.4$	0.96	172.7
		mean	231.7	0.99	62.2	0.97	169.5
Axial strain with alignment feature	(με)	1	$1.10 \pm 0.08$	0.97	$1.09 \pm 0.10$	0.95	0.01
		2	$1.13 \pm 0.08$	0.96	$1.13 \pm 0.02$	0.99	0.00c
		mean	1.12	0.97	1.11	0.97	0.01
Temperature with alignment feature	(degree Celsius)	1	$8.44 \pm 0.16$	0.99	$9.58 \pm 0.31$	0.99	$- 1.14$
		2	$8.45 \pm 0.13$	0.99	$9.53 \pm 0.31$	0.99	$- 1.08$
		3	$8.41 \pm 0.14$	0.99	$9.55 \pm 0.31$	0.99	$- 1.14$
		mean	8.43	0.99	9.55	0.99	$- 1.12$

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Applied Optics