EGU21-11824
https://doi.org/10.5194/egusphere-egu21-11824
EGU General Assembly 2021
© Author(s) 2021. This work is distributed under
the Creative Commons Attribution 4.0 License.

Prediction of Petrophysical Properties from Seismic Inversion and Neural Network: A case study

Siddharth Garia1, Arnab Kumar Pal2, Karangat Ravi3, and Archana M Nair4
Siddharth Garia et al.
  • 1Research Scholar, Indian Institute of Technology Guwahati, Department of Civil Engineering, Guwahati, India (sidd_41@iitg.ac.in)
  • 2Research Scholar, Indian Institute of Technology Guwahati, Department of Civil Engineering, Guwahati, India (arnab.pal@iitg.ac.in)
  • 3Assistant Professor, Indian Institute of Technology Guwahati, Department of Civil Engineering, Guwahati, India (ravi.civil@iitg.ac.in)
  • 4Assistant Professor, Indian Institute of Technology Guwahati, Department of Civil Engineering, Guwahati, India (nair.archana@iitg.ac.in)

Seismic inversion method is widely used to characterize reservoirs and detect zones of interest, i.e., hydrocarbon-bearing zone in the subsurface by transforming seismic reflection data into quantitative subsurface rock properties. The primary aim of seismic inversion is to transform the 3D seismic section/cube into an acoustic impedance (AI) cube. The integration of this elastic attribute, i.e., AI cube with well log data, can thereafter help to establish correlations between AI and different petrophysical properties. The seismic inversion algorithm interpolates and spatially populates data/parameters of wells to the entire seismic section/cube based on the well log information. The case study presented here uses machine learning-neural network based algorithm to extract the different petrophysical properties such as porosity and bulk density from the seismic data of the Upper Assam basin, India. We analyzed three different stratigraphic  units that are established to be producing zones in this basin.

 AI model is generated from the seismic reflection data with the help of colored inversion operator. Subsequently, low-frequency model is generated from the impedance data extracted from the well log information. To compensate for the band limited nature of the seismic data, this low-frequency model is added to the existing acoustic model. Thereafter, a feed-forward neural network (NN) is trained with AI as input and porosity/bulk density as target, validated with NN generated porosity/bulk density with actual porosity/bulk density from well log data. The trained network is thus tested over the entire region of interest to populate these petrophysical properties.

Three seismic zones were identified from the seismic section ranging from 681 to 1333 ms, 1528 to 1575 ms and 1771 to 1814 ms. The range of AI, porosity and bulk density were observed to be 1738 to 6000 (g/cc) * (m/s), 26 to 38% and 1.95 to 2.46 g/cc respectively. Studies conducted by researchers in the same basin yielded porosity results in the range of 10-36%. The changes in acoustic impedance, porosity and bulk density may be attributed to the changes in lithology. NN method was prioritized over other traditional statistical methods due to its ability to model any arbitrary dependency (non-linear relationships between input and target values) and also overfitting can be avoided. Hence, the workflow presented here provides an estimation of reservoir properties and is considered useful in predicting petrophysical properties for reservoir characterization, thus helping to estimate reservoir productivity.

How to cite: Garia, S., Pal, A. K., Ravi, K., and Nair, A. M.: Prediction of Petrophysical Properties from Seismic Inversion and Neural Network: A case study, EGU General Assembly 2021, online, 19–30 Apr 2021, EGU21-11824, https://doi.org/10.5194/egusphere-egu21-11824, 2021.

Displays

Display file