In this paper, we will discuss the probabilistic seismic inversion of Bonga main reservoirs, with the objective of updating the reservoir static models with the net sand prediction from seismic.
A unique solution to the seismic inverse problem does not exist. Uncertainties arise from two sources: noise in the seismic data and ambiguities in the inverse problem itself. Ambiguities are mainly caused by the fact that the seismic data are band limited. Most inversion algorithms, often guided by well and horizon constraints, typically produce a single solution. This solution may represent the most likely subsurface model but it does not give information about other possible solutions.
For the results discussed in this paper, we used a trace-by-trace based inversion that relies upon rock and fluid property relationships that describe acoustic properties (Vp, Vs, density) as a function of reservoir properties (e.g. porosity, net-to-gross etc). A prior model is provided as input. This prior model is the initial reservoir static model from which the rock and fluid properties are obtained. These properties are then perturbed in a statistical manner for a number of iterations, deriving acoustic impedances which are used to generate the corresponding synthetic traces. These synthetic traces are then compared with the actual seismic response, and selected against a matching criterion such as semblance. The probabilistic approach combines the seismic modelling with a statistically correct examination of uncertainties taking into account noise in the seismic data. As no well is used to constrain the inversion, this allows for blind well information to be used as validation points for the inversion results.
This procedure, in addition to providing the "most likely" model, also provides a statistical examination of uncertainties.
Introduction
Shell Nigeria Exploration and Production Company is currently using a Shell proprietary application to run probabilistic seismic inversion on the Bonga main reservoirs, with the objective of updating the static models with the net sand prediction from seismic. Probabilistic seismic inversion fully accounts for uncertainties in reservoir properties and noise in the seismic data, such that the inherent uncertainties are captured in the net sand predicted. By constraining the derivation of the net sand with the seismic data, we will have statistically appropriate estimates of the correctness of the input static model.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.