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1 March 2011 Simultaneous measurement of three parameters using an all-fiber Mach-Zehnder interferometer based on suspended twin-core fibers
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Abstract
We describe an all-fiber Mach-Zehnder interferometric configuration based on a suspended twin-core fiber. Because of the birefringence of the fiber cores, two interferometers are obtained by illuminating the fiber with polarized light. Applying strain, curvature, and temperature to the sensing head, different sensitivities are observed that permit the use of the matrix method to discriminate these three measurands.

1.

Introduction

The twin-core fiber was first demonstrated as a temperature sensor in 1983 by Meltz 1 The temperature sensitivity of a twin-core fiber sensor with a single cladding and the circular cores is due almost entirely to the linear expansion of the core and the thermo-optic effect. Peng 2 fabricated a twin-core optical fiber with a large elliptical core with significant polarization-dependent coupling properties. On the other hand, Tjugiarto 3 observed that the coupling between the two cores increases with the spin rate in a spun twin-core fiber. In 2000, Gander 4 proposed a two-axis bend measurement using multicore optical fiber. MacPherson 5 demonstrated a curvature sensor using a twin-core photonic crystal fiber, and Flockhart 6 reported two-axis bend measurement using Bragg gratings written in multicore optical fiber.

In this work, the authors propose a new sensing head based on a Mach–Zehnder interferometric configuration using a suspended twin-core fiber. This sensing head presents different sensitivities when subjected to strain, curvature, and temperature. The possibility of simultaneous measurement using the matrix method to discriminate the three parameters is also demonstrated.

2.

Experimental Setup and Results

Figure 1 presents the experimental setup with the sensing head based on a suspended twin-core fiber. Light from a broadband source in the 1550-nm window was linearly polarized with a polarizer and injected into the suspended twin-core fiber with a length of 33 cm. A polarization controller was used to optimize the polarization states (x- and y-axes), and all the measurements were performed with an optical spectrum analyzer. The fiber cross section is shown also in Fig. 1. The suspended twin-core fiber with four holes made of pure silica was fabricated at the Institute of Photonic Technology (Jena, Germany). The distance between the two cores is ∼6.4 μm, being possible to simultaneously illuminate the two cores using a standard single-mode fiber (SMF-28®). The core's diameter is 1.5 μm, the cladding is 124 μm, and the big and small holes are 10 and 5 μm, respectively.

Fig. 1

Experimental setup of the Mach–Zehnder interferometric configuration based on the suspended twin-core fiber and photos of the fiber cross section.

030501_1_1.jpg

Because of the fiber geometry, the triangular-shaped cores in the suspended twin-core fiber presents birefringence and two discrete Mach–Zehnder interferometers can be excited. The first interferometer is obtained when the polarized light excites only the x-polarization state in the two cores. The second interferometer appears when the input linear polarized light is along the y-axis. In these situations, we have a single Mach–Zehnder interferometer, where each arm is an eigenaxis of each core, originating a typical two-wave channeled spectrum, which can be observed in Figs. 2 and 2. When the input polarized light is along a direction that excites the two eigenaxes of the two cores, a beat of the two single interferometers appears, as is evident in Fig. 2.

Fig. 2

Spectral response of the interferometric structure for input polarized light along the (a) x-axis, (b) y-axis, and (c) when both axes of the two cores are excited.

030501_1_2.jpg

From the channeled spectrum periodicity [Figs. 2 and 2], it turns out that the effective refractive index difference for the light propagating in the two cores is 7.6 × 10−4 (x polarization) and 8.1 × 10−4 (y polarization) in the 1550-nm wavelength region.

Because of the small diameter of the cores, there is a substantial evanescent field of the propagating light. Consequently, the waveguide dispersion is not negligible, which is evident from the data shown in Fig. 2, particularly in the case of excitation of the two x- and y-polarization Mach–Zehnder interferometers, as is clear in Fig. 2. Around the wavelengths λ1 ∼ 1546 nm, λ2 ∼ 1554 nm, and λ3 ∼ 1560 nm, the periodicity of the channeled spectrum is ∼1.96, ∼1.70, and ∼2.60 nm, respectively. Also, it was observed that the dependence with curvature, strain, and temperature of the peaks associated with these three wavelengths were all different, providing an opportunity to perform simultaneous measurement of these three parameters.

To test this possibility, first the behavior of this structure as a curvature sensor was characterized.7 Hence, the fiber was fixed at two points at a distance of 540 mm from each other and submitted to specific curvature values by using a translation stage (via successive 100–μm displacements). The spectral position of the maximums associated with λ1, λ2, and λ3 have different and linear responses to curvature variations, as shown in Fig. 3, with sensitivity coefficients of (–1.38±0.07) nm/m−1, (–1.42±0.07) nm/m−1, and (–1.35 ±0.05) nm/m−1, respectively.

Fig. 3

Dependence on curvature of the peaks associated with λ1, λ2, and λ3 in Fig. 2.

030501_1_3.jpg

The response to temperature variations of the sensing head was also characterized.8 The structure was placed in a tube furnace and submitted to increasing values of temperature in the range 0–100°C, with 10°C steps. The results shown in Fig. 4 indicate that the wavelength peaks λ1, λ2, and λ3 have linear responses to temperature variations, characterized by the sensitivities: (28.2±0.8), (34.9±0.8), and (33.5±0.8) pm/°C for λ1, λ2, and λ3, respectively.

Fig. 4

Dependence on temperature of the peaks associated with λ1, λ2, and λ3 in Fig. 2.

030501_1_4.jpg

The sensing structure was also characterized in terms of strain. The input and output fibers were accordingly fixed at two points 540 mm apart and submitted to specific strain values by using a translation stage (via successive 10-μm displacements). The results are made available in Fig. 5. Once again, the wavelength peaks have linear responses to strain variations, with sensitivities: (5.4±0.01), (5.0±0.01), and (5.6±0.01) pm/μɛ, for λ1, λ2, and λ3, respectively.

Fig. 5

Dependence on strain of the peaks associated with λ1, λ2, and λ3 in Fig. 2.

030501_1_5.jpg

The sensitivity coefficients obtained for curvature, temperature, and strain applied to the proposed sensing structure indicates the feasibility to perform simultaneous measurement of these measurands. From the experimental sensitivity coefficients, comes the following:

Eq. 1

[TeX:] \documentclass[12pt]{minimal}\begin{document}\begin{eqnarray} \left[ {\begin{array}{*{20}c} {\Delta \lambda _1 } \\ {\Delta \lambda _2 } \\ {\Delta \lambda _3 } \\ \end{array}} \right] &=& \left[ {\begin{array}{*{20}c} {K_{T1} } & {K_{\varepsilon 1} } & {K_{C1} } \\ {K_{T2} } & {K_{\varepsilon 2} } & {K_{C2} } \\ {K_{T3} } & {K_{\varepsilon 3} } & {K_{C3} } \\ \end{array}} \right]\!\!\left[ {\begin{array}{*{20}c} {\Delta T} \\ {\Delta \varepsilon } \\ {\Delta C} \\ \end{array}} \right] \!\Rightarrow\! \left[ {\begin{array}{*{20}c} {\Delta \lambda _1 } \\ {\Delta \lambda _2 } \\ {\Delta \lambda _3 } \\ \end{array}} \right]\nonumber \\& =& \left[ {\begin{array}{*{20}c} { - 28.2} & { - 5.4} & { - 1.34} \\ { - 34.9} & { - 5.0} & { - 1.37} \\ { - 33.5} & { - 5.6} & { - 1.41} \\ \end{array}} \right]\!\!\left[ {\begin{array}{*{20}c} {\Delta T} \\ {\Delta \varepsilon } \\ {\Delta C} \\ \end{array}} \right]. \end{eqnarray}\end{document} Δλ1Δλ2Δλ3=KT1Kɛ1KC1KT2Kɛ2KC2KT3Kɛ3KC3ΔTΔɛΔCΔλ1Δλ2Δλ3=28.25.41.3434.95.01.3733.55.61.41ΔTΔɛΔC.
This matrix equation can be inverted, resulting in

Eq. 2

[TeX:] \documentclass[12pt]{minimal}\begin{document}\begin{equation} \left[\! \begin{array}{l} \Delta T \\ \Delta \varepsilon \\ \Delta C \\ \end{array}\! \right] \!=\! \left[\! {\begin{array}{*{20}c} {0,3104} & {0,0549} & { - 0,3484} \\ {1,6540} & {2,5594} & { - 4,0587} \\ { - 13,9449} & { - 11,4694} & {23,6874} \\ \end{array}} \!\right]\!\!\left[\! \begin{array}{l} \Delta \lambda _1 \\ \Delta \lambda _2 \\ \Delta \lambda _3 \\ \end{array}\! \right]. \end{equation}\end{document} ΔTΔɛΔC=0,31040,05490,34841,65402,55944,058713,944911,469423,6874Δλ1Δλ2Δλ3.
A factor of merit of an approach of this type is the value of the determinant of the coefficient matrix in Eq. 1. When its magnitude is close to zero that means that some sensitivity coefficients are similar, therefore, compromising the effectiveness of the simultaneous measurement functionally. Thus, desirably, the value must be as large as possible and, in the present case, it is ∼26, which is large enough to achieve an effective measurement performance with this sensing configuration.9

3.

Conclusions

A new sensing head based on a Mach–Zehnder interferometric configuration based on a suspended twin-core fiber was proposed. Because of the birefringence of the cores, in the presence of input light with a polarization state that excites the two eigenaxes of the two cores, a double interferometer is present, originating beat phenomena. Because of the waveguide dispersion of the light that propagates in the cores, the variation with curvature, temperature, and strain of a particular fringe of the beat channeled spectrum depends on the wavelength. This feature opens the possibility of simultaneous measurement of these three parameters.

Acknowledgments

This work was supported by the COST 299—Optical Fibres for New Challenges Facing the Information Society.

References

1. 

G. Meltz, J. R. Dunphy, W. W. Morey, and E. Snitzer, “Cross-talk fibre-optic temperature sensor,” Appl. Opt., 22 464 –477 (1983). https://doi.org/10.1364/AO.22.000464 Google Scholar

2. 

G. D. Peng, T. Tjugiarto, and P. L. Chu, “Twin-core optical fibre with large core ellipticity,” Appl. Opt., 30 632 –634 (1991). https://doi.org/10.1364/AO.30.000632 Google Scholar

3. 

T. Tjugiarto, P. L. Chu, and G. D. Peng, “The twin-elliptic-core optical fibre polarization splitting,” 994 –997 (1990). Google Scholar

4. 

M. J. Gander, D. Macrae, E. A. C. Galliot, R. McBride, J. D. C. Jones, P. M. Blanchard, J. G. Burnett, A. H. Greenaway, and M. N. Inci, “Two-axis bend measurement using multicore optical fibre,” Opt. Commun., 182 115 –121 (2000). https://doi.org/10.1016/S0030-4018(00)00817-8 Google Scholar

5. 

W. N. MacPherson, M. J. Gander, R. McBride, J. D. C. Jones, P. M. Blanchard, J. G. Burnett, A. H. Greenaway, B. Mangan, T. A. Birks, J. C. Knight, and P. S. Russell, “Remotely addressed optical fibre curvature sensor using multicore photonic crystal fibre,” Opt. Commun., 193 97 –104 (2001). https://doi.org/10.1016/S0030-4018(01)01260-3 Google Scholar

6. 

G. M. H. Flockhart, W. N. MacPherson, J. S. Barton, J. D. C. Jones, L. Zhang, I. Bennion, “Two-axis bend measurement with Bragg gratings in multicore optical fibre,” Opt. Lett., 28 387 –389 (2003). https://doi.org/10.1364/OL.28.000387 Google Scholar

7. 

W. C. Du, H. Y. Tam, M. S. Y. Liu, and X. M. Tao, “Long-period fibre grating bending sensors in laminated composite structures,” Proc. SPIE, 3330 284 –292 (1998). https://doi.org/10.1117/12.316984 Google Scholar

8. 

T. Martynkien, M. Szpulak, W. Urbanczyk, “Modeling and measurement of temperature sensitivity in birefringent photonic crystal holey fibres,” Appl. Opt., 44 7780 –7788 (2005). https://doi.org/10.1364/AO.44.007780 Google Scholar

9. 

W. Jin, W. C. Michie, G. Thursby, M. Konstantaki, and B. Culshaw, “Simultaneous measurement of strain and temperature: error analysis,” Opt. Eng., 36 598 –609 (1997). https://doi.org/10.1117/1.601233 Google Scholar
©(2011) Society of Photo-Optical Instrumentation Engineers (SPIE)
Susana F. Oliveira Silva, Orlando Frazão, José Luís Santos, Jens Kobelke, and Kay Schuster "Simultaneous measurement of three parameters using an all-fiber Mach-Zehnder interferometer based on suspended twin-core fibers," Optical Engineering 50(3), 030501 (1 March 2011). https://doi.org/10.1117/1.3553482
Published: 1 March 2011
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Cited by 12 scholarly publications.
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KEYWORDS
Optical fibers

Head

Polarization

Interferometers

Interferometry

Birefringence

Temperature metrology

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