A protocol to create a full-range linear displacement sensor, combining two packaged fiber Bragg grating detectors with a magnetic scale, is presented.
Long-distance displacement measurements using optical fibers have always been a challenge in both basic research and industrial production. We developed and characterized a temperature-independent fiber Bragg grating (FBG)-based random-displacement sensor that adopts a magnetic scale as a novel transferring mechanism. By detecting shifts of two FBG center wavelengths, a full-range measurement can be obtained with a magnetic scale. For identification of the clockwise and counterclockwise rotation direction of the motor (in fact, the direction of movement of the object to be tested), there is a sinusoidal relationship between the displacement and the center wavelength shift of the FBG; as the anticlockwise rotation alternates, the center wavelength shift of the second FBG detector shows a leading phase difference of around 90° (+90°). As the clockwise rotation alternates, the center wavelength shift of the second FBG displays a lagging phase difference of around 90° (-90°). At the same time, the two FBG-based sensors are temperature independent. If there is some need for a remote monitor without any electromagnetic interference, this striking approach makes them a useful tool for determining the random displacement. This methodology is appropriate for industrial production. As the structure of the whole system is relatively simple, this displacement sensor can be used in commercial production. In addition to it being a displacement sensor, it can be used to measure other parameters, such as velocity and acceleration.
Optical fiber-based sensors have great advantages, such as flexibility, wavelength division multiplexing, remote monitoring, corrosion resistance, and other characteristics. Thus, the optical fiber displacement sensor has broad applications.
To realize targeted linear displacement measurements in complex environments, various structures of the optical fiber (e.g., the Michelson interferometer1, the Fabry-Perot cavity interferometer2, the fiber Bragg grating3, the bending loss4) have been developed over recent years. The bending loss requires the light source in a stable station and is unsuitable for environmental vibration. Qu et al. have designed an interferometric fiber-optic nanodisplacement sensor based on a plastic dual-core fiber with one end coated with a silver mirror; it has a resolution of 70 nm5. A simple displacement sensor based on a bent single-mode-multimode-single-mode (SMS) fiber structure was proposed to overcome the limitations on the measurement of the displacement range; it increased the displacement sensitivity threefold with a range from 0 to 520 µm6. Lin et al. presented a displacement sensor system that combines the FBG together with a spring; the output power is approximately linear with the displacement of 110-140 mm7. A fiber Fabry-Perot displacement sensor has a measurement range of 0-0.5 mm with a linearity of 1.1% and a resolution of 3 µm8. Zhou et al. reported a wide-range displacement sensor based on a fiber-optic Fabry-Perot interferometer for subnanometer measurements, up to 0.084 nm over a dynamic range of 3 mm9. A fiber-optic displacement sensor based on reflective intensity modulated technology was demonstrated using a fiber collimator; this had a sensing range over 30 cm10. Although optical fibers can be fabricated into many kinds of displacement sensors, these fiber-based sensors generally make use of the tensile limit of the material itself, which limits their application in wide-range measurements. Thus, compromises are usually made between the measurement range and sensitivity. Moreover, it is difficult to determine the displacement as various variables occur simultaneously; especially, cross-sensitivity of the strain and temperature could damage the experimental precision. There are many discrimination techniques reported in the literature, such as using two different sensing structures, using a single FBG half-bonded by different glues, or using special optical fibers. Thus, the further development of optical fiber displacement sensors requires high sensitivity, a small size, great stability, full range, and temperature independence.
Here, the periodic structure of the magnetic scale makes a full-range measurement possible. A random displacement without a limited measurement range with a magnetic scale is achieved. Combined with two FBGs, both temperaturecross-sensitivity and the identification for the direction of movement could be solved. Various steps within this method require precision and attention to detail. The protocol of the sensor fabrication is described in detail as following.
1. Fabrication of the fiber Bragg grating
2. Preparation of the magnetic scale and the matching clamp
3. Fabrication of the displacement sensor
4. Building the testing system
5. Evaluation of the designed displacement sensor
The distance, ranging from 1 mm to 3 mm11, between the magnetic scale and the detector enabled the detection of the linear displacement with a sinusoidal function. A distance of 22.5 mm between two detectors enabled this approach to realize detection of the direction of an object's movement with a phase difference of 90°. The two detectors were separated from each other for (m ± 1/4)τ (m is a positive integer) and (m ± 1/4)τ ≤ the total length of the magnetic scale, where τ = 10 mm and m = 2 are used in the experiment described here (Figure 1). The composition and structure of the displacement detector are shown in Figure 2. The key of the packaging process is to apply a preloaded force to the FBG; when there was a movement, the magnetic force between the magnetic scale and the detector would change (Figure 3), and the axis stress distribution of the FBG would be uniform as the spring stretched or compressed. The measurement system is based on the ASE, the interrogator, and the OSA, which characterizes the sensor's center wavelength signature (Figure 4). The OSA, with a minimum resolution of 0.02 nm, was more accurate than the interrogator when measuring the spectrum statically. OSA has a high resolution; it is more suitable than the interrogator in static calibration experiments.
The results of static calibration (Figure 5a) and corresponding residual errors (Figure 5b) revealed that the designed detector allows the exploration of the random-displacement position at its best. For the identification of the forward and inverse movement direction of the motor, as the forward movementalternates, the center wavelength shift of the 2#FBG detector has a leading phase difference of around 90° (+90°). As the inverse displacement alternates , the center wavelength shift of the 2#FBG displayed the sinusoidal function variations by a lagging phase difference of around 90° (-90°) (Figure 6). The temperature cross-sensitivity on the proposed sensor could be eliminated by a differential sine function. A positive or negative change in the phase angle could be obtained. The direction of the displacement could easily be solved, as mentioned previously12. In brief, the data collected from the temperature calibration experiment is shown in Figure 7. It can be known that the temperature sensitivity (KT) of both FBG detectors is the same when the temperature interference is not ignored in this system. The relationship between the displacement and the wavelength shifts can be expressed as follows; thus, temperature compensation is the merit of this system.
The uncertainty from the data fitting shows that the maximum uncertainty is almost parallel with the maximum amplitude of the sinusoidal fitting curve. There can be some improvement to make uncertainty smaller so that the uncertainty represents the property of the sensor. We took the balanced point (5 mm, a position in which the detector is opposite in polarity to the magnetic scale) and the maximum amplitude (2.5 mm, a position in which the detector has polarity to the magnetic scale) of 1#FBG as an example (depicted in Figure 5b), and the repeatability of the measurement (10 counts) is shown in Figure 8. It is clear that the balanced point (5 mm) was more stable than the maximum amplitude (2.5 mm), and the maximum residual error (7.5 pm) occurred on the maximum amplitude (2.5 mm) of 1#FBG. The accuracy of the displacement measurement is 0.69 µm.
Automatic control and production, especially for machine monitoring in serious oil-contaminated circumstances, need optical fiber-based long displacement. Thus, the designed optical fiber sensor can be used in steel and iron process.
Figure 1: The magnetic scale and matching clamp. Please click here to view a larger version of this figure.
Figure 2: Composition and structure of the displacement detector. Please click here to view a larger version of this figure.
Figure 3: Method of applied preloaded force during packaging. Please click here to view a larger version of this figure.
Figure 4: Experiment setup for displacement measurements. The system is based on the ASE, the interrogator, and the OSA, which characterize the sensor's center wavelength signature. This figure is reprinted with permission from Zhu et al.11. Please click here to view a larger version of this figure.
Figure 5: Static calibration and residual errors. (a) The relationship between the displacement and the two FBGs wavelength shift. (b) The fitting curve residual error between the original data and the sinusoidal curve. This figure is reprinted with permission from Zhu et al.11. Please click here to view a larger version of this figure.
Figure 6: Identification of the clockwise and counterclockwise rotation direction of the motor. This figure is reprinted with permission from Zhu et al.11. Please click here to view a larger version of this figure.
Figure 7: The relationship between the center wavelength and temperature. This figure is reprinted with permission from Zhu et al.11. Please click here to view a larger version of this figure.
Figure 8: The repeatability of the measurement. Please click here to view a larger version of this figure.
Name | Parameters |
Magnetic Grade | N35 |
Magnet Material | NdFeB |
Surface & Coating | Nickel |
Magnetizing direction | N/S pole on both sides of the plane |
Size | D5 x 4 mm |
M(magnetization) | 750 [kA/m] |
Table 1:Description of the permanent magnet. This table is reprinted with permission from Zhu et al.11.
Tipo | Steps | Displacement/step (μm) |
A | 1,600 | 312 |
B | 2,000 | 250 |
C | 3,200 | 156 |
D | 4,000 | 125 |
E | 6,400 | 78 |
F | 12,800 | 40 |
Table 2: Description of the microstep driver.
We have demonstrated a new method for random linear displacement measurements by combining a magnetic scale and two fiber Bragg gratings. The main advantage of these sensors is random displacement without limitation. The magnetic scale used here generated a periodicity of the magnetic field at 10 mm, far beyond the practical limits of conventional optical fiber displacement sensors, such as the displacement mentioned by Lin et al.7 and Li et al.8. The temperature-dependent displacement sensor is also suitable for experiments involved in remote monitoring.
The preloaded force on the FBG is the critical step in the packaging protocol of the FBG-based magnetic detector. When the spring is stretched or compressed, a uniform axis stress distribution of the FBG is obtained. A distance of (m ± 1/4)τ between two detectors is essential to ensure that the entire system recognizes the direction of movement.
This new displacement measurement technology requires a reduced susceptibility to vibration. The sensors may also be improved by reducing their sensitivity to humidity changes, which are affected by the spring in the detector. Future work could focus on the development of software algorithms to eliminate vibration affection. This displacement sensor system can become commercially available if the pitch of the magnetic scale can be decreased as the commercial electronic magnetic scale.
This sensor can be used to measure random displacement without range limitation with respect to existing methods. Although the protocol here has been proven to be effective as a displacement sensor, it can also be used to measure other parameters, such as velocity and acceleration.
The authors have nothing to disclose.
The authors thank the Optics Laboratory for their equipment and are thankful for financial support through the Program for Changjiang Scholars and Innovative Research Team in University and the Ministry of Education of China.
ASE | OPtoElectronics Technology Co., Ltd. | 1525nm-1610nm | |
computer | Thinkpad | win10 | |
fiber cleaver/ CT-32 | Fujikura | the diameter of 125 | |
fiber optic epoxy /DP420 | henkel-loctite | Ratio 2:1 | |
interrogator | BISTU | sample rate:17kHz | |
motor driver | Zolix | PSMX25 | |
optical circulator | Thorlab | three ports | |
optical couple | Thorlab | 50:50 | |
optical spectrum analyzer/OSA | Fujikura | AQ6370D | |
permanent magnet | Shanghai Sichi Magnetic Industry Co., Ltd. | D5x4mm | |
plastic shaped pipe | Topphotonics | ||
power source | RIGOL | adjustable power | |
single mode fiber | Corning | 9/125um | |
Spring | tengluowujin | D3x15mm | |
stepper motor controller | JF24D03M |