Overcoming Performance Limitations of Distributed Brillouin Fiber Laser Sensors
A technical analysis of the effectiveness of distributed Brillouin fiber laser sensing (DBFLS) in overcoming performance limitations of existing Brillouin sensors in structural health monitoring and environmental sensing applications.
Distributed fiber sensors are a powerful tool for structural health monitoring and environmental sensing due to their ability to remotely monitor the strain at 1,000s of locations using low-cost optical fiber. Sensors based on Brillouin scattering are uniquely suited to these tasks since they can make completely distributed, absolute measurements of strain, with a long range (>100 km), small sensing size (<1 cm), and a huge absolute dynamic range, all in standard off-the-shelf telecom fiber. These sensors function by measuring the resonance frequency of the non-linear Brillouin interaction in fiber which shifts linearly with strain and temperature.
However, existing Brillouin sensors are hampered by fundamentally poor response resulting in small frequency shifts compared to the linewidth of the interaction. To overcome this limitation we introduced a technique known as distributed Brillouin fiber laser sensing (DBFLS) which establishes a series of narrowband lasing modes that experience Brillouin gain at discrete locations.
Brillouin fiber sensors are able to make fully distributed absolute strain and temperature measurements using standard telecom fiber. Brillouin sensors have been demonstrated with large dynamic range and operating at long distances with high spatial resolution. These aspects have made Brillouin sensors well suited for a number of applications, particularly in structural health monitoring. However, these sensors exhibit poor sensitivity when compared to other fiber sensing modalities such as fiber Bragg gratings or Rayleigh scattering. Ultimately this weak sensitivity comes from the inherently low strain and temperature response of the Brillouin frequency shift compared to the linewidth of the interaction (despite the relatively narrow linewidth of the Brillouin resonance, ~30 MHz), resulting in poor signal to noise ratio (SNR).
To overcome this limitation we proposed to use the linewidth narrowing effects associated with the lasing transition to greatly improve the SNR. Brillouin fiber lasers have previously been demonstrated with very narrow linewidths by leveraging the already narrowband nature of the interaction. However these fiber cavities, while sensitive to strain and temperature, are sensitive to these changes anywhere in the cavity and could not be used to make distributed measures. Here we use a pulsed pump to excite a series of lasing modes in a fiber cavity. The pump pulse period is carefully tuned to match the round trip time in lasing cavity such that the lasing modes only experience Brillouin gain at distinct locations in the fiber under test (FUT). The frequency of the lasing modes then matches the Brillouin resonance frequency and is responsive to changes in temperature or strain at only one position each.
My Karle fellowship was proposed to create, demonstrate, and investigate the performance of a distributed Brillouin fiber laser sensor. During the fellowship I produced an initial prototype and presented the basic noise performance, bandwidth and dynamic range. This was followed up with investigations into noise scaling with sensor spatial resolution. This work was then extended to practical lengths and numbers of sensors while addressing a weakness in the initial design where the fiber was not contiguously sampled.
This work was performed by Joseph Murray, for the Naval Research Laboratory. For more information, download the Technical Support Package (free white paper) at mobilityengineeringtech.com/tsp under the Sensors category. NRL-5670
This Brief includes a Technical Support Package (TSP).
Distributed Brillouin Fiber Laser Sensor
(reference NRL-5670) is currently available for download from the TSP library.
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