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What are Fiber Optic Sensing and Fiber Bragg Grating?

  • Contents

Overview: The article overviews fiber optic sensing technology, discusses principles and sensor classifications, highlights the concept of Bragg reflectors and Fiber Bragg Grating Sensors, and discusses their applications in various domains.

 

Fiber optic sensing technology in engineering has grown significantly and marks substantial progress in the measuring and monitoring domains.

What is an optical fiber?

It is a versatile medium for light transmission. Optic fiber, as shown in Fig. 1, comprises,

  • Core: Thinner than human hair and transmits light signals
  • Cladding: Confines the light inside the core
  • Coating: Made of silica or plastic

Fig. 1 Cross section of optic fiber

Fig. 1: Cross section of optic fiber

Fiber Optic Sensing

Using optical fibers, fiber optic sensing is a method that monitors changes in pressure, temperature, strain, and other characteristics. It works by measuring the degree to which intrinsic light parameters are modulated by external environmental factors that impact the way light waves move through optical fibers. It can function as single-mode fiber or multimode fiber.

Principles of Optic Fibers Sensing

Total internal reflection is the principle by which optic fibers work. When light is coming from a denser medium into a rarer (less dense) medium, it is reflected back into the original medium if the angle of incidence of the light is smaller than the critical angle. The reflected light is then analyzed to determine its physical properties.

 

The optical fiber experiences variations in temperature, pressure, and strain, which can alter its electromagnetic wave characteristics like amplitude, frequency, phase, and polarization.

 

The pivotal role of optic fiber sensors is decoding, or demodulating, and determining the level of pressure, strain, and temperature that is being applied to the fiber, as shown in Fig. 2. This facilitates the sensing of different physical quantities in the immediate surroundings. These core features of optical fiber and cable make them useful for addressing various issues in the real world.

Fig. 2 Diagrammatic illustration of optic fibers sensing technology

Fig. 2 Diagrammatic illustration of optic fibers sensing technology

 

Advantages

Compared to conventional sensing methods, optical fiber sensors provide several benefits. These advantages include:

  • Remain unaffected by high temperatures, strain, and pressure
  • The capacity to multiplex several sensors along a single fiber
  • Resistance to electromagnetic interferences
  • Easily available components
  • Non-destructive
  • Compact size
  • Non-invasive

Classification of Optical Fibers Sensors

Fiber-optic sensors can be classified as

  • Intrinsic sensors
  • Extrinsic sensors

Intrinsic Sensor

Intrinsic sensor sensing happens inside the optical fiber itself. Fiber indicates the variations caused by external stimuli by measuring the level of changes in the light's internal characteristics, like wavelength, polarization, intensity, phase, and transit time.

 

There are several uses for intrinsic sensors, including measurement of temperature, pressure, strain, and other applications. Large-scale distributed sensing is something they can offer, which is very helpful for applications that need to monitor across vast distances or in difficult circumstances.

Extrinsic Sensor

When sensing occurs outside the optical fiber, it is called an extrinsic sensor. The optical fiber in these sensors serves as a channel for light to go and come from the external sensing device. After exiting the fiber cable, the light beam interacts with the object being measured and is carried by optic fiber to a photodetector, which detects the changes in light.

What is grating?

Generally, a grating is any regularly spaced group of parallel, elongated, almost similar fragments.

What is a Bragg reflector?

A Bragg reflector, as shown in Fig. 3, is a form of optical reflector that is commonly utilized in optical fibers and many laser applications. It is made up of two separate dielectric materials layered in alternating order, each with a different refractive index. The Bragg reflector's main role is to reflect some light wavelengths while permitting others to pass through.

Fig. 3 Illustration of Fiber Bragg Grating

Fig. 3: Illustration of Fiber Bragg Grating

 

Fiber Bragg Grating

In the field of optical engineering, a particular kind of grating is called Fiber Bragg Grating (FBG). A brief section of optical fiber is used to create a distributed Bragg reflector, which transmits all other light wavelengths while reflecting specific ones.

 

This is accomplished by giving regular fluctuations in the refractive index of the optic fiber. FBGs are employed in wavelength-specific sensing applications to block certain wavelengths. The reflected wavelength is also referred to as the Bragg wavelength.

Interrogation Techniques

The important step in FBG sensors is finding the shift in the Bragg wavelength that reflects the change in the physical parameter. Various methods of inquiry have been devised to precisely and effectively demodulate the Bragg wavelength shifts. The following are some essential methods:

Spectrometer-Based Interrogation Technique

FBG sensor wavelength interrogation is done using an optical spectrum analyzer. OSAs are precision instruments and essential tools in environmental sensing. However, they are costly, which makes them less attractive for certain functions.

Tunable Laser-Based Interrogation

When examining FBG sensors, a laser with adjustable wavelengths is used to scan the reflected Bragg wavelength from the FBG. This technique is known as tunable laser-based interrogation. The intensity of the reflected light is tracked.

 

An observable peak in reflected intensity occurs when the laser wavelength and the Bragg wavelength coincide. The precise location of this peak makes it possible to measure the physical modifications that resulted in the shift in the Bragg wavelength.

 

Tunable laser-based interrogation devices can be costly and difficult despite their advantages.

Matched Edge Filter Configuration

This technique uses matching edge filter interrogation, which can be an affordable way to do sensing without compromising measurement precision.

Application of FBG Sensors

FBG sensors have a wide variety of applications in various domains, including:

Energy

  • Wind turbines
  • Solar panel
  • Nuclear plants
  • Electrical equipment
  • Oil

Medical and Biotech

  • Physiological parameter monitoring includes cardiac activity, respiratory activity, etc.
  • Invasive surgery

Structural Health Monitoring

  • Strain and defect detector in civil structure
  • Electrical instruments

Transportation

  • Aerospace
  • Railways
  • Ship
  • Space

Perimeter sensing

  • Security
  • Military

Geotechnical monitoring

  • Landslide
  • Seismic activity

 

In conclusion, the evolution of fiber optic sensing technology has significantly enhanced monitoring and measurement capabilities across various industries. Bragg reflectors and interrogation methods like tunable laser-based methods have improved as sensor types, and Fiber Bragg Grating sensors have found more uses in the energy, medical, transportation, and structural health monitoring fields.

 

These innovations underscore the importance of fiber optic sensing in enabling precise and reliable data collection for critical operations, paving the way for further advancements in the field of optical fiber sensing.

 

Summarizing the Key Points

  • Fiber optic sensing technology offers precise monitoring of pressure, temperature, and strain using optical fibers, revolutionizing measurement capabilities in various industries.
  • Sensor classifications include intrinsic and extrinsic sensors, each serving distinct purposes in detecting external stimuli within or outside the optical fiber.
  • Bragg reflectors, such as Fiber Bragg Grating Sensors, utilize regular refractive index fluctuations to reflect specific wavelengths, enabling wavelength-specific sensing applications.
  • These fiber optic sensing technology advancements have diverse applications in the energy, medical, transportation, and security sectors, enhancing monitoring and measurement efficiency in real-world scenarios.

 

Reference

Pendão, Cristiano, and Ivo Silva. “Optical Fiber Sensors and Sensing Networks: Overview of the Main Principles and Applications.” Sensors 22, no. 19 (October 5, 2022): 7554. https://doi.org/10.3390/s22197554.

Kersey, A.D., M.A. Davis, H.J. Patrick, M. LeBlanc, K.P. Koo, C.G. Askins, M.A. Putnam, and E.J. Friebele. “Fiber Grating Sensors.” Journal of Lightwave Technology 15, no. 8 (1997): 1442–63. https://doi.org/10.1109/50.618377.

Rakesh Kumar, Ph.D.

Rakesh Kumar holds a Ph.D. in electrical engineering, specializing in power electronics. He is a Senior Member of the IEEE Power Electronics Society, Class of 2021. He writes high-quality, long-form technical articles for global B2B semiconductor brands. Feel free to reach out to him at rakesh.a@ieee.org! Checkout his complete portfolio @muckrack.com/rakesh-kumar-phd | @linkedin.com/in/rakesh-kumar-phd

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