Interpretation of borehole sonic measurements acquired in vertical transversely isotropic formations penetrated by vertical wells

Abstract: Detecting vertical transversely isotropic (VTI) formations and quantifying the magnitude of anisotropy are fundamental for describing organic mudrocks. Methods used to estimate stiffness coefficients of VTI formations often provide discontinuous or spatially averaged results over depth intervals where formation layers are thinner than the receiver aperture of acoustic tools. We have developed an inversion-based method to estimate stiffness coefficients of VTI formations that are continuous over the examined de… Show more

“…In a horizontally stratified rock formation penetrated by a vertical borehole, the spatial averaging effects inherent to the borehole acoustic instrument can be derived from wave propagation equations or the ray‐tracing method. The forward model for a layered formation is given by (Huang et al., 2015; Maalouf & Torres‐Verdín, 2018b) $$$$\begin{equation} \bar{s}\left(d,f\right)\approx \sum _{i\hspace*{0.28em}}F\left({z}_{i}\right)s\left({z}_{i},f\right), \end{equation}$$$$where $$\bar s( {d,f} )$$ is the fast modelled frequency‐dependent slowness measured at depth $$d$$ and frequency $$f$$, $$s( {{z_i},f} )$$ is the formation slowness at depth $${z_i}$$ (between the i th and the $$i+1$$th receivers) and frequency $$f$$, while $$F$$ is the axial averaging function introduced by the geometry of the acoustic instrument with m receivers and given by (Maalouf & Torres‐Verdín, 2018b) $$$$\begin{equation} F\hspace*{0.28em}\left({z}_{i}\right)=\frac{6i\left(m-i\right)}{m\left({m}^{2}-1\right)}\hspace*{0.28em}. \end{equation}$$$$Figure 7 shows the axial spatial...…”

“…$$F( {\bf{m}} )$$ is the operator that performs axial averaging; 𝛼, $${{\bf{W}}_{\bf{d}}},$$$${{\bf{W}}_{\bf{e}}}$$ and $${\mathbf{m}}_{\mathrm{ref}}$$ are regularization parameter, regularization weighting matrix, data misfit weighting matrix and reference parameter vector for regularization (when needed), respectively. In the examples considered in this paper, $$\alpha \; = \;0$$ as regularization, that is, regularization is not implemented because the layers are thicker or slightly thinner than the full width at the half‐maximum of function $$F$$ (Maalouf & Torres‐Verdín, 2018b). With much thinner layers identified, first‐ or second‐order Tikhonov regularization for $${{\bf{W}}_{\bf{d}}}$$ can be implemented to bias a preference for a ‘flat’ or ‘smooth’ solution, respectively.…”

“…In a horizontally stratified rock formation penetrated by a vertical borehole, the spatial averaging effects inherent to the borehole acoustic instrument can be derived from wave propagation equations or the ray-tracing method. The forward model for a layered formation is given by (Huang et al, 2015;Maalouf & Torres-Verdín, 2018b)…”

“…where s(𝑑, 𝑓 ) is the fast modelled frequency-dependent slowness measured at depth 𝑑 and frequency 𝑓 , 𝑠(𝑧 𝑖 , 𝑓 ) is the formation slowness at depth 𝑧 𝑖 (between the ith and the 𝑖 + 1th receivers) and frequency 𝑓 , while 𝐹 is the axial averaging function introduced by the geometry of the acoustic instrument with m receivers and given by (Maalouf & Torres-Verdín, 2018b)…”

Radial profiling of shear slowness from borehole acoustic measurements acquired in thinly laminated formations

“…In a horizontally stratified rock formation penetrated by a vertical borehole, the spatial averaging effects inherent to the borehole acoustic instrument can be derived from wave propagation equations or the ray‐tracing method. The forward model for a layered formation is given by (Huang et al., 2015; Maalouf & Torres‐Verdín, 2018b) $$$$\begin{equation} \bar{s}\left(d,f\right)\approx \sum _{i\hspace*{0.28em}}F\left({z}_{i}\right)s\left({z}_{i},f\right), \end{equation}$$$$where $$\bar s( {d,f} )$$ is the fast modelled frequency‐dependent slowness measured at depth $$d$$ and frequency $$f$$, $$s( {{z_i},f} )$$ is the formation slowness at depth $${z_i}$$ (between the i th and the $$i+1$$th receivers) and frequency $$f$$, while $$F$$ is the axial averaging function introduced by the geometry of the acoustic instrument with m receivers and given by (Maalouf & Torres‐Verdín, 2018b) $$$$\begin{equation} F\hspace*{0.28em}\left({z}_{i}\right)=\frac{6i\left(m-i\right)}{m\left({m}^{2}-1\right)}\hspace*{0.28em}. \end{equation}$$$$Figure 7 shows the axial spatial...…”

“…$$F( {\bf{m}} )$$ is the operator that performs axial averaging; 𝛼, $${{\bf{W}}_{\bf{d}}},$$$${{\bf{W}}_{\bf{e}}}$$ and $${\mathbf{m}}_{\mathrm{ref}}$$ are regularization parameter, regularization weighting matrix, data misfit weighting matrix and reference parameter vector for regularization (when needed), respectively. In the examples considered in this paper, $$\alpha \; = \;0$$ as regularization, that is, regularization is not implemented because the layers are thicker or slightly thinner than the full width at the half‐maximum of function $$F$$ (Maalouf & Torres‐Verdín, 2018b). With much thinner layers identified, first‐ or second‐order Tikhonov regularization for $${{\bf{W}}_{\bf{d}}}$$ can be implemented to bias a preference for a ‘flat’ or ‘smooth’ solution, respectively.…”

“…In a horizontally stratified rock formation penetrated by a vertical borehole, the spatial averaging effects inherent to the borehole acoustic instrument can be derived from wave propagation equations or the ray-tracing method. The forward model for a layered formation is given by (Huang et al, 2015;Maalouf & Torres-Verdín, 2018b)…”

“…where s(𝑑, 𝑓 ) is the fast modelled frequency-dependent slowness measured at depth 𝑑 and frequency 𝑓 , 𝑠(𝑧 𝑖 , 𝑓 ) is the formation slowness at depth 𝑧 𝑖 (between the ith and the 𝑖 + 1th receivers) and frequency 𝑓 , while 𝐹 is the axial averaging function introduced by the geometry of the acoustic instrument with m receivers and given by (Maalouf & Torres-Verdín, 2018b)…”

Radial profiling of shear slowness from borehole acoustic measurements acquired in thinly laminated formations

High-Resolution Sonic Slowness Estimation Based on the Reconstruction of Neighboring Virtual Traces

Determination of the elastic parameters of a VTI medium from sonic logging data using deep learning