Distributed Fiber-optic Acoustic Sensor with Long Sensing Range over 100 km and Sub-nano Strain Resolution

2019 IEEE International Instrumentation and Measurement Technology Conference (I2MTC) Pub Date : 2019-05-01 DOI:10.1109/I2MTC.2019.8826827

Dian Chen, Qingwen Liu, Zuyuan He

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Abstract

The measurement distance is one of the most important parameters for distributed acoustic sensor (DAS). In this paper, we report a long-distance and high-sensitivity DAS system based on time-gated digital optical frequency domain reflectometry (TGD-OFDR). The bi-directional distributed Raman amplification is adopted to realize long measurement distance. The interference fading and polarization fading are well suppressed, and hence phase demodulation method can be adopted, instead of intensity demodulation method. As a result, the sensitivity is enhanced and the full information (amplitude, phase and frequency) of the vibration can be obtained. In experiments, the fiber length is about 108 km, while the spatial resolution is 5 m. A weak vibration with peak-peak amplitude of $14.7 \mathrm {n}\varepsilon $ is correctly located at the distance of 98 km with a high SNR of 30 dB. It is the first time that $220- \mathrm {p}\varepsilon / \surd$ Hz strain sensitivity is realized over 100-km-level fiber and the vibration waveform is retrieved linearly without harmonics.

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分布式光纤声传感器，传感范围超过100公里，亚纳米应变分辨率

测量距离是分布式声传感器的重要参数之一。本文报道了一种基于时间门控数字光频域反射(TGD-OFDR)的远距离高灵敏度DAS系统。采用双向分布式拉曼放大，实现远距离测量。干涉衰落和极化衰落被很好地抑制，因此可以采用相位解调方法代替强度解调方法。从而提高了灵敏度，获得了振动的全部信息(振幅、相位和频率)。实验中，光纤长度约为108 km，空间分辨率为5 m。一个峰值振幅为14.7 \ mathm {n}\varepsilon $的弱振动正确定位在98 km的距离上，信噪比高达30 dB。这是首次在100公里级光纤上实现$220- \ mathm {p}\varepsilon / $ surd$ Hz应变灵敏度，并实现无谐波线性反演。

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2019 IEEE International Instrumentation and Measurement Technology Conference (I2MTC)

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