Abstract
We show that the use of random optical grating using UV exposure (ROGUE) can significantly reduce the noise floor of an optical frequency domain reflectometry (OFDR) measurement of Faraday rotation in the polarization. We compare it with unexposed spun fiber, which shows a S/P minimum ratio (signal noise floor) 20 dB higher than when using our ROGUE. High sensitivity magnetic field measurements are achieved by spatially filtering (setting a gage length) the derivative of the S/P ratio’s evolution. An example of a calibrated electromagnet spatially resolved B-field measurement is demonstrated, which can measure fields down to 10 mT with 10 cm spatial resolution. The potential for current sensing using the ROGUE apparatus is discussed and simulation shows a noise floor of ∼1 A with 40 probing loops spatial resolution.
© 2024 Optica Publishing Group under the terms of the Optica Open Access Publishing Agreement
1. Introduction
Optical fiber sensors have shown great advantage in many fields thanks to their remote sensing capability, their immunity to electromagnetic noise, their tolerance to harsh environmental conditions and their high sensitivity [1]. In addition, optical fiber can be used for distributed sensing, offering spatially resolved continuous sensing data. This can be extremely useful for high-precision modeling, such as in shape sensing [2], and to view localized events, such as faults, which is crucial in many safety monitoring applications [3]. In this paper, we are interested in distributed magnetic field measurements, which can be extended to high-current monitoring (also known as all-fiber optic current transformer (AFOCT)) [4]. Distributed magnetic field is critical in applications where the shape of the field is important to know and model, such as in Tokamaks [5], industrial magnets in motors [6] and medical MRI systems [7]. Distributed current monitoring can be useful in high-current industrial applications to monitor several loads in a single measurement or to detect faults before catastrophic failures.
Highly sensitive optical fiber magnetic sensors [8] have been demonstrated through strain measurement induced by magnetostriction [9,10] or through phase measurement of a surrounding fluid [11]. In both cases, while the sensitivity is very good (3 to 10 mT noise floor), the fiber needs to interact with a magnetic responsive solid or fluid, requiring complex and expensive sensor fabrication procedure that can hardly be scaled to long lengths. Another means of measurement is through Faraday rotation [12], where field is measured by integrating the polarization rotation along a long length of fiber, typically loops around a current source. Although such sensors can be very sensitive (typically a measurement floor from few A to few kA, depending on fiber coiling), they are limited to a single integrated measurement with no spatial information. Palmieri et al. have shown distributed current sensing by polarization analysis through optical frequency domain reflectometry (OFDR) of Rayleigh back-scattering in standard fiber [13], which resulted in a noise floor of ∼100 A for 11 m of optical fiber length (40 loops) resolution.
OFDR distributed sensing of Rayleigh back-scattering has shown many sensing applications (temperature, strain, vibration & shape), but always suffers from very weak signal coming back to the interrogator. Various techniques have been proposed to increase such signals, such as UV exposure of fiber [14], continuous weak fiber Bragg grating (FBG) writing [15] or FBG arrays [16]. This latter technique was demonstrated as distributed magnetic sensor in Tokamaks [5]. However, continuous FBGs have the disadvantage of limited length due to having all the signal being reflected, while FBG arrays suffer from large manufacturing cost and blind spots between gratings. A recently proposed solution is to use incoherent FBG, a Random Optical Grating using UV or fs exposure (ROGUE), which is not only very inexpensive to manufacture (being noise-generated), but also offers a large-bandwidth significantly enhanced return signal while maintaining a long operation length [17]. A broad-spectrum grating is equivalent to having multiple weaker coherent gratings sensors in parallel. For the same maximum reflectivity, which limits sensing distance (i.e. the insertion losses with distance), a random grating will have significantly more return signal compared to a coherent grating, hence increasing the signal-to-noise ratio (SNR). In contrast, for the same SNR, a ROGUE will have significantly less insertion losses per distance, hence allowing longer distributed sensors. In this paper, we apply for the first time these random gratings to magnetic measurement, which requires a completely different methodology compared to previous distributed measurement using random gratings [17]. We demonstrate how such a ROGUE’s enhanced signal can significantly lower the noise floor of an OFDR magnetic measurement, thus making possible the measurement of low field with cm-scale spatial resolutions.
2. Principle of operation
The principle of operation relies on the ability of an OFDR optical back-reflectometer (OBR) to measure the spatial distribution of 2 orthogonal polarization states: $S(z )$ and $P(z )$ (linearly polarized at the detectors). If the state entering the fiber under test (FUT) at $z = 0$ is linearly polarized, then the polarization will rotate by $\theta = VBz$ as it propagates in the fiber under a magnetic field B along its z-axis, where V is the Verdet constant of the material ($V \approx 0.6\; \textrm{rad}/({\textrm{T}\cdot \textrm{m}} )$ for silica optical fiber [13]). This optical activity is caused by magnetically induced weak circular birefringence. Therefore, it is crucial for the linear birefringence of the medium to be either null or very small. This is why magnetic or current sensing is typically done in spun fiber, which offers circular birefringence. Through the Faraday rotation principle, the reflected light will continue to rotate in the same direction, yielding a total rotation angle of $\theta = 2VBz$. If we extinguish one polarization to its minimum at $z = 0$ (S-polarization in this paper) by setting the input state with a polarization controller (PC), then the distributed signal will be:
The field can then be expressed as the derivative of the amplitude signal of the S/P ratio:
This can be further improved by using higher-order filtering technique. In this paper, we use a 3-step filtering: a logarithmic pre-smoothing (moving average), a large area derivative and a post-smoothing. These steps can be represented by the following discretization:
The first step (Eq. (5a)) is a moving average in log-scale and is used to condition the signal for the derivative. The log-scale averaging is preferable to a linear scale averaging as it brings the discrete points to the same order of magnitude, thus significantly reduces signal deterioration from the derivative. The second step (Eq. (5b)) is a M-points central derivative, required to recover the magnetic field. The last step is a final linear smoothing using the same window (M data) to reduce post-derivative noise. As it uses the same window size, this last step causes minimal sacrifice on the resolution. From a numerical analysis of the noise, this 3-step filtering gives a ${\sigma _B} \propto \mathrm{\Delta }{z^{ - 1.7}}$ dependance for the resulting magnetic field noise and decreases it. For instance, the STD level is reduced by a factor of 65 resolution compared to the single-step filter of Eq. (3) in the case of $\mathrm{\Delta }z = 4$ cm.
3. Magnetic sensing characterization
Our random gratings (ROGUEs) are written using a Talbot interferometer, as shown in Fig. 1(a). In this setup, the fiber is moved continuously under a fringe pattern. The intrinsic noise of the motor induces FBG writing over a coherence length equal to the spot size. Hence, the natural bandwidth of the ROGUE is inversely proportional to the spot size. The strength and bandwidth of the ROGUE can be tuned through coherence control by sending a random noise amplitude to a piezoelectric element moving the phase-mask [17]. Figure 1(b) shows the total spectra of the 40 cm ROGUE used in this paper written at 100 µm/s using 80 mW of 213 nm UV power and adding a random 2$\pi $ random phase at 10 Hz.
The grating should yield a uniform amplitude back-reflection spatial profile when averaged over a few spot-size lengths (∼1 cm) to ensure uniform sensor performance and must not induce birefringence. It should be noted that the exact spectral shape (coherent or random FBG) is irrelevant to the sensor’s sensitivity performance. A broader spectrum will yield, for the SNR, a lower insertion loss and allow for longer operating lengths.
To demonstrate distributed magnetic measurement using ROGUE, the setup shown in Fig. 2(a) is used. The interrogation system is composed of a commercial OFDR system from LUNA (OBR4600) connected to a polarization controller (PC) to adjust the polarization at the input of the FUT, which is optimized to have the highest extinction of the S-polarization at zero-field, which is an arbitrary choice to better visualize the measurement. A higher extinction ratio can be reached with the ROGUE (26 dB vs 11 dB for unexposed fiber) as the suppressed polarization’s amplitude is much farther from the OBR noise level. The residual S-signal – caused by imperfect extinction ratio of the LUBA system and residual linear birefringence – is not problematic, as we calculate the derivative.
A PM delivery fiber (SM panda type) is used between the interrogation system and the measurement location (3-meters away) to ensure bending insensitivity of the delivery fiber. The FUT is composed of a section of spun fiber (section A, Fibercore SHB1500) and a 40 cm ROGUE (section B) written in hydrogen loaded SMF-28. Section B is then placed in an Helmholtz electromagnet (double coil) in axial configuration. Two calibrated electromagnets were used for tests: a double water-cooled copper-coiled magnet which can reach 400 mT at its center (Mag1) and a superconducting magnet capable of reaching 5 T (Mag2). Calibration was done prior to our measurement (producing current-field curves) using Hall-effect sensors (Lakeshore 421). In the case of Mag1, the coils each have a ferromagnetic core, which concentrates a uniform strong field between the 2 cores. The cores have an air-hole at their center in which the field is near zero (isolated by the ferromagnetic material) and are used to insert the fiber. In such configuration, an abrupt uniform (near square-shaped) magnetic field is expected in the area between the cores, which is a good test profile to characterize both noise (in uniform region) and resolution (on the edges).
Figure 2(b) shows the distributed signal S and P of section A and B after PC optimization. With the ROGUE’s significant increase in back-scattering, the P-signal is increased by 45 dB compared to the bare spun fiber. According to Eq. (3), this should give a significant advantage to the ROGUE fiber in terms of noise level, which becomes very apparent when comparing the resulting magnetic field calculation on both FUT, as shown in Fig. 2(c). The disadvantage of a large $\mathrm{\Delta z}$ also becomes obvious on the edge of the ROGUE, where information becomes corrupted without noise from beyond.
Result of distributed field measurement in Mag1 for a $\mathrm{\Delta }z = \; 2\; $cm is shown in Fig. 3(a). The field between the coils is constant as should be expected in a Helmholtz configuration. The resulting PSF for a fictive highly localized field is shown in Fig. 3(a). This PSF is used to define the $\mathrm{\Delta }z$ as its FWHM. Calibration of the Verdet constant, which may vary from fiber to fiber, is done by comparing results of Eq. (2) with the calibrated measured field value. The fiber must be straight along the axial axis of the coils to ensure a measurement of the same field as that of the calibrated probes. The average Faraday rotation angle derivative in the constant region of the Helmholtz coils is shown for various expected magnetic fields in Fig. 3(b). for both Mag1 and Mag2. The corresponding Verdet constant is 0.63 rad/m/T, close to previous values in the literature [9]. It is important to note that linearity is well persevered for high fields, where P and S get to similar values. Hence, in this case, we can consider that the weak linear birefringence has little impact on the quality of the measurement.
As the noise level is highly related to the chosen $\mathrm{\Delta }z$, an analysis of the impact of spatial filtering on the noise is shown in Fig. 4. Results of a ROGUE are compared to the unexposed spun fiber, where an improvement of one order of magnitude is shown. Noise level of 10 mT can be reached with a large resolution of over 8 cm.
4. Discussion on current measurement
Being able to measure magnetic field also allows us to measure electrical current. To do so, the optical fiber needs to be coiled around the current source cable. If we consider an integration of N loops of circumference C, the current can be measured as:
The same spatial filters of Eq. (5) are applied to define a spatial resolution $\mathrm{\Delta }z$, which can now be considered as an “integration length”, as depicted by Eq. (6) . It should be noted that since the fiber is looped around the wire, the signal resolution $\mathrm{\Delta }z$ in the optical fiber is necessarily much longer than the current resolution $\mathrm{\Delta }{z_e}$ along the wire. To get an idea of how such ROGUE could potentially perform for current sensing, we extrapolated the noise modeled in Fig. 4 to large $\mathrm{\Delta }z = NC$ and calculated equivalent current noise level in Fig. 5. Considering that this would correspond to a current distributed measurement resolution of $\mathrm{\Delta }{z_e} = N\mathrm{\Lambda }$, we associated a N integrated loop number to the minimum possible resolution using a pitch of 250 µm (optical fiber diameter). As can be seen in Fig. 5, for OFDR typical sensing length (∼50 m), sub-amp current could be resolved for $\mathrm{\Delta }z = 15$ m resolution ($\mathrm{\Delta }{z_{e\; min}} = 1.25$ cm). Further improvement would require using time-domain reflectometry (OTDR) instead to probe longer lengths of ROGUES.
5. Conclusions
In conclusion, we’ve demonstrated the use of continuous random fiber Bragg grating (ROGUE) as a magnetic distributed sensor using Faraday rotation. To do so, a polarization analysis approach must be used instead of the traditional frequency-shift (phase derivative or cross-correlation) approach used in temperature or strain sensing. We propose a new and optimized data filtering process to minimize the noise of the magnetic field recovery derivative calculation. The higher signal to noise ratio of ROGUE yields (40 dB) a significantly improved performance in terms of measured magnetic noise floor compared to unexposed spun fiber, the standard fiber used for magnetic measurements. The higher SNR of ROGUE makes it significantly more robust to pre-FUT component losses and enables faster measurements with less gain. By extrapolating our results to longer lengths, we can predict that ROGUEs can reach high current sensitivity (∼100 mA or less) in distributed measurements, enabling precise fault detection in electrical installations. Ideal ROGUEs should be written in spun fiber in order to reduce the influence of parasitic linear birefringence. This presents a challenge in the writing process due to periodic rotating stress rods, which will be tackled in future work.
Funding
Polytechnique Montréal (PIED).
Disclosures
The authors declare no conflicts of interest.
Data availability
Data underlying the results presented in this paper are not publicly available at this time but may be obtained from the authors upon reasonable request.
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