Distributed Acoustic Sensing Using Chirped-Pulse Phase-Sensitive OTDR Technology

Abstract: In 2016, a novel interrogation technique for phase-sensitive (Φ)OTDR was mathematically formalized and experimentally demonstrated, based on the use of a chirped-pulse as a probe, in an otherwise direct-detection-based standard setup: chirped-pulse (CP-)ΦOTDR. Despite its short lifetime, this methodology has now become a reference for distributed acoustic sensing (DAS) due to its valuable advantages with respect to conventional (i.e., coherent-detection or frequency sweeping-based) interrogation strategies. Pr… Show more

“…In CP-φOTDR, the pulse-to-pulse frequency scanning is replaced by a single linearly chirped pulse probe signal [38,39]. Given a chirped-pulse bandwidth much larger than the transform-limited pulse bandwidth, any external temperature or strain induced changes in the fiber optical path will translate into a local time shift (at the corresponding optical trace position).…”

“…Consequently, CP-φOTDR sensors are not only able of detecting and localizing an external stimulus, but they are also able of quantifying them with high accuracy. In addition, CP-φOTDR ensures a consistent value of sensitivity along the length of the fiber, without being affected by the fading points (which are positions with nearly no visibility affecting conventional φOTDR traces) [38,39]. Therefore, CP-φOTDR sensors are extremely appealing for applications that need to quantify a certain physical parameter over large distances and that require a similar measuring quality in all points along the fiber, being widely implemented in areas going from security to seismology [33,34].…”

“…Therefore, CP-φOTDR sensors are extremely appealing for applications that need to quantify a certain physical parameter over large distances and that require a similar measuring quality in all points along the fiber, being widely implemented in areas going from security to seismology [33,34]. Currently, CP-φOTDR has shown to reach sub-mK resolutions over ranges of up to 100 km with metric spatial resolution and sampling rates of the order of 1 kHz [39], reaching more recently a record dynamic strain sensitivity of 10 −12 ε/ √ Hz (equivalent to 10 −6 K/ √ Hz) [43]. Working principle of chirped-pulses in phase-sensitive optical time domain reflectometry (CP-φOTDR): A linear frequency chirped pulse is sent into the optical fiber.…”

“…The experimental setup used in the proposed proof-of-concept demonstration of a distributed solar irradiance sensor is depicted in Figure 3. The sensor is a CP-φOTDR interrogator [38,39], whose operation has been already described in section 2. Working principle of chirped-pulses in phase-sensitive optical time domain reflectometry (CP-φOTDR): A linear frequency chirped pulse is sent into the optical fiber.…”

“…Recently, an advanced optical fiber reflectometry technique using chirped-pulses in phase-sensitive optical time domain reflectometry (CP-φOTDR) has been demonstrated to achieve sub-mK resolutions in distributed temperature detection, achieving fast (kHz) and reliable measurements over distances of up to 100 km with meter-scale spatial resolutions [38][39][40]. With these advances, it is now possible to develop a feasible and practical distributed surface solar irradiance sensor using optical fibers.…”

Long-Range Distributed Solar Irradiance Sensing Using Optical Fibers

“…In CP-φOTDR, the pulse-to-pulse frequency scanning is replaced by a single linearly chirped pulse probe signal [38,39]. Given a chirped-pulse bandwidth much larger than the transform-limited pulse bandwidth, any external temperature or strain induced changes in the fiber optical path will translate into a local time shift (at the corresponding optical trace position).…”

“…Consequently, CP-φOTDR sensors are not only able of detecting and localizing an external stimulus, but they are also able of quantifying them with high accuracy. In addition, CP-φOTDR ensures a consistent value of sensitivity along the length of the fiber, without being affected by the fading points (which are positions with nearly no visibility affecting conventional φOTDR traces) [38,39]. Therefore, CP-φOTDR sensors are extremely appealing for applications that need to quantify a certain physical parameter over large distances and that require a similar measuring quality in all points along the fiber, being widely implemented in areas going from security to seismology [33,34].…”

“…Therefore, CP-φOTDR sensors are extremely appealing for applications that need to quantify a certain physical parameter over large distances and that require a similar measuring quality in all points along the fiber, being widely implemented in areas going from security to seismology [33,34]. Currently, CP-φOTDR has shown to reach sub-mK resolutions over ranges of up to 100 km with metric spatial resolution and sampling rates of the order of 1 kHz [39], reaching more recently a record dynamic strain sensitivity of 10 −12 ε/ √ Hz (equivalent to 10 −6 K/ √ Hz) [43]. Working principle of chirped-pulses in phase-sensitive optical time domain reflectometry (CP-φOTDR): A linear frequency chirped pulse is sent into the optical fiber.…”

“…The experimental setup used in the proposed proof-of-concept demonstration of a distributed solar irradiance sensor is depicted in Figure 3. The sensor is a CP-φOTDR interrogator [38,39], whose operation has been already described in section 2. Working principle of chirped-pulses in phase-sensitive optical time domain reflectometry (CP-φOTDR): A linear frequency chirped pulse is sent into the optical fiber.…”

“…Recently, an advanced optical fiber reflectometry technique using chirped-pulses in phase-sensitive optical time domain reflectometry (CP-φOTDR) has been demonstrated to achieve sub-mK resolutions in distributed temperature detection, achieving fast (kHz) and reliable measurements over distances of up to 100 km with meter-scale spatial resolutions [38][39][40]. With these advances, it is now possible to develop a feasible and practical distributed surface solar irradiance sensor using optical fibers.…”

Long-Range Distributed Solar Irradiance Sensing Using Optical Fibers

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