Machine learning as a seismic prior velocity model building method for full-waveform inversion: a case study from Colombia

We use machine learning algorithms (artificial neural networks, ANNs) to estimate petrophysical models at seismic scale combining well-log information, seismic data and seismic attributes. The resulting petrophysical images are the prior inputs in the process of full-waveform inversion (FWI). We cal...

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Detalles Bibliográficos
Autores: Iturrarán-Viveros, Ursula, Muñoz-García, Andrés M., Castillo Reyes, Octavio|||0000-0003-4271-5015, Shukla, Khemraj
Tipo de recurso: artículo
Fecha de publicación:2021
País:España
Institución:Universitat Politècnica de Catalunya (UPC)
Repositorio:UPCommons. Portal del coneixement obert de la UPC
Idioma:inglés
OAI Identifier:oai:upcommons.upc.edu:2117/336859
Acceso en línea:https://hdl.handle.net/2117/336859
https://dx.doi.org/10.1007/s00024-021-02655-9
Access Level:acceso abierto
Palabra clave:Machine learning
Neural networks (Computer science)
Seismic engineering data report
Artificial neural networks
Full-waveform inversion
Velocity-model building
Nonlinear least squares
Seismic attributes
Terratrèmols -- Amèrica del Sud
Colòmbia
Àrees temàtiques de la UPC::Enginyeria civil::Geotècnia
Descripción
Sumario:We use machine learning algorithms (artificial neural networks, ANNs) to estimate petrophysical models at seismic scale combining well-log information, seismic data and seismic attributes. The resulting petrophysical images are the prior inputs in the process of full-waveform inversion (FWI). We calculate seismic attributes from a stacked reflected 2-D seismic section and then train ANNs to approximate the following petrophysical parameters: P-wave velocity (Vp), density (ρ) and volume of clay (Vclay). We extend the use of the Vclay by constraining it with the well lithology and we establish two classes: sands and shales. Consequently, machine learning allows us to build an initial estimate of the earth property model (Vp), which is iteratively refined to produce a synthetic seismogram that matches the observed seismic data. We apply the 1-D Kennett method as a forward modeling tool to create synthetic data with the images of Vp, ρ and the thickness of layers (sands or shales) obtained with the ANNs. A nonlinear least-squares inversion algorithm minimizes the residual (or misfit) between observed and synthetic full-waveform data, which improves the Vp resolution. In order to show the advantage of using the ANN velocity model as the initial velocity model for the inversion, we compare the results obtained with the ANNs and two other initial velocity models. One of these alternative initial velocity models is computed via P-wave impedance, and the other is achieved by velocity semblance analysis: root-mean-square velocity (RMS). The results are in good agreement when we use ρ and Vp obtained by ANNs. However, the results are poor and the synthetic data do not match the real acquired data when using the semblance velocity model and the ρ from the well log (constant for the entire 2-D section). Nevertheless, the results improve when including ρ, the layered structure driven by the Vclay (both obtained with ANNs) and the semblance velocity model. When doing inversion starting with the initial Vp model estimated using the P-wave impedance, there is some gain of the final Vp with respect to the RMS initial Vp. To assess the quality of the inversion of Vp, we use the information for two available wells and compare the final Vp obtained with ANNs and the final Vp computed with the P-wave impedance. This shows the benefit of employing ANNs estimations as prior models during the inversion process to obtain a final Vp that is in agreement with the geology and with the seismic and well-log data. To illustrate the computation of the final velocity model via FWI, we provide an algorithm with the detailed steps and its corresponding GitHub code.