Enhancement of sensing range of Brillouin optical time‐domain reflectometry system up to 150 km with in‐line bi‐directional erbium‐doped fibre amplifications

Abstract: Brillouin optical time‐domain reflectometry (BOTDR) has the advantage of requiring access to only one end of the sensing fibre, which is an important property for some applications. The coherent detection of spontaneous Brillouin scattering allows high sensitivity of temperature/strain measurements, close to one of the well‐known Brillouin optical time‐domain analyser‐based solutions. In‐line amplification based on bidirectional erbium‐doped fibre amplification (EDFA) modules can improve sensing distance and t… Show more

“…1,2 The use of a single-photon avalanche detector (SPAD) makes it possible to measure optical signals at very low flux, up to -120 dBm and consequently to increase the range of the distributed sensors. [3][4][5][6] This solution avoids amplifying the optical signal along the fiber under test (FUT) using EDFA modules 7,8 or Raman amplification. 9 We present here a system called ν-BOTDR using SPAD, allowing to measure the Brillouin response.…”

Single-photon detector based long-distance Brillouin optical time domain reflectometry

“…1,2 The use of a single-photon avalanche detector (SPAD) makes it possible to measure optical signals at very low flux, up to -120 dBm and consequently to increase the range of the distributed sensors. [3][4][5][6] This solution avoids amplifying the optical signal along the fiber under test (FUT) using EDFA modules 7,8 or Raman amplification. 9 We present here a system called ν-BOTDR using SPAD, allowing to measure the Brillouin response.…”

Single-photon detector based long-distance Brillouin optical time domain reflectometry

Long-Range and High Spatial Resolution Brillouin Time Domain Sensor Using Oversampling Coding and Deconvolution Algorithm

Towards single-photon Brillouin optical time domain reflectometry