Distributed Acoustic Sensing in Geophysics. Группа авторов

Distributed Acoustic Sensing in Geophysics

alt="StartRoot 2 slash upper N EndRoot"/>. For both heterodyne and/or homodyne phase detection, the photons number halves again (Kazovsky, 1989), as sine and cosine signal components should be measured independently, and so the noise rises to StartRoot 4 slash upper N EndRoot

. Direct photodetection at λ = 1550nm is not sufficiently sensitive, so DAS usually uses an erbium doped fiber amplifier (EDFA) to boost the signal, which introduces additional noise. This noise can be simply represented by a noise figure N_F ≈ 3, which can be reached with appropriate optical filtering as explained in Kirkendall & Dandridge (2004). In this case, the shot noise limit is then given by:

(1.45) normal upper Phi Subscript min Baseline equals StartFraction 1 Over upper V EndFraction StartRoot StartFraction 4 upper N Subscript upper F Baseline Over upper N EndFraction EndRoot tilde 10 Superscript negative 4 Baseline italic r a d slash StartRoot italic upper H z EndRoot

where visibility, V = 0.5, includes all other system imperfections such as polarization mismatch. Equation 1.45 represents the white noise level for 1 second time integration of the DAS signal. For engineered fiber, the number of photons can be up to 100 times larger than for conventional Rayleigh backscattering, so the noise will be 10 times smaller.

Another advantage of DAS with engineered fiber is a wider dynamic range that is defined as the ratio of the maximum detectable signal to the noise level. The typical geophone bandwidth is ΔF = 100Hz, so the minimum strain level ε_min detectable for DAS for gauge length L₀ = 10m within the same detection bandwidth is:

(1.46) epsilon Subscript min Baseline equals StartFraction normal upper Phi Subscript min Baseline upper A 0 StartRoot normal upper Delta upper F EndRoot Over upper L 0 EndFraction tilde 0.01 italic nanostrain

where A₀ = 115nm is the elongation corresponding to one radian phase shift (Equation 1.14).

Experimental measurements with conventional fiber DAS found a value three times higher, at 0.03nanostrain (Miller et al., 2016). In this case, there was some extra flicker noise, as discussed earlier (see Figure 1.11). Here, a spiky noise structure corresponds to algorithm discontinuities that amplify photodetector noise, with a spectrum after DAS signal time integration, which is ∝F⁻¹. The typical low frequency limit when excessive noise starts to dominate over shot noise is between 10 and 100 Hz, depending on the fiber conditions.

For engineered fiber (Farhadiroushan et al., 2021), reflectivity can be engineered to be hundreds of times higher than the normal Rayleigh level, without any significant problems with crosstalk, such that R = 100 · R_BS · τ = − 45dB. As a result, sensitivity is ten times higher, at around 1picostrain, which corresponds to a 100x (20 dB) improvement in acoustic signal sensitivity.

It is important to compare the shot noise level of DAS with the noise level of high‐sensitivity geophones and seismometers. The DAS white noise value should be added to flicker noise with coefficient μ and corrected for spatial filtering (Equation 1.46) as:

(1.47)

The comparison in Figure 1.28 demonstrates that DAS sensitivity is compatible with geophones. The noise spectrum data for Sercel SG5‐SG10 was adapted from Fougerat et al. (2018), and the seismometer Streckeisen STS‐2 data from Ringler & Hutt (2010) and Wielandt & Widmer‐Schnidrig (2002).

The sensitivity of DAS can even be improved at low frequencies by extending the gauge length from L₀ = 10m to L₀ = 30m, but at the cost of increased noise at frequencies of more than 70 Hz. Also, 30 m data for DAS with engineered fiber is presented with synthetic gauge length optimization (Equation 1.44). It is worth mentioning that this optimization can be effectively applied to DAS with engineered fiber only, as it has no significant pink noise and can be effectively spatially averaged. As is clear from Figure 1.29, the performance of DAS with engineered fiber can reach seismometers, and it is deep below Peterson’s low noise model level (Peterson, 1993). So, the engineered fiber antenna is an equivalent of a set of multiple seismic stations and can be used for passive seismic applications. Moreover, DAS with engineered fiber has unique sensing capability below 1 Hz, where gravitational wave detectors have limited environmental isolation (Matichard et al., 2015); DAS can be potentially used for such applications.

We now turn our attention to the increase in dynamic range achievable using DAS with an engineered fiber. The acoustic algorithm transforms DAS intensity signals into a phase shift proportional to the fiber elongation value. The algorithm is based on an ambiguous function such as ATAN(x), which give a valid result only inside a limited region (Itoh, 1982). As was analyzed in Section 1.1 (titled ‘Distributed Acoustic Sensor (DAS) Principles and Measurements’), a set of different algorithms can be used, depending on the order of phase tracking. For the first and second order, we have:

(1.48) negative pi less-than-or-equal-to upper A 1 left-parenthesis t right-parenthesis less-than pi

(1.49) negative pi less-than-or-equal-to upper A 2 left-parenthesis t plus StartFraction 1 Over upper F Subscript s Baseline EndFraction right-parenthesis minus upper A 2 left-parenthesis t right-parenthesis less-than pi

For limits (Equations 1.48–1.49), it is clear that the maximum recoverable strain ε_1,2 will depend on the algorithm order 1 or 2, and can also be increased using a higher sampling frequency F_s. For a harmonic signal cos(2πFt), we can normalize strain results as:

(1.50) epsilon 1 less-than-or-equal-to StartFraction upper A 0 Over 2 upper L 0 EndFraction StartFraction upper F Subscript upper S Baseline Over upper F EndFraction

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