Simultaneous assimilation of production and seismic data: application to the Norne field

Automatic history matching using production and seismic data is still challenging due to the size of seismic datasets. The most severe problem, when applying ensemble-based methods for assimilating large datasets, is that the uncertainty is usually underestimated due to the limited number of models...

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Bibliographic Details
Published in:Computational geosciences 2020-04, Vol.24 (2), p.907-920
Main Authors: Lorentzen, Rolf J., Bhakta, Tuhin, Grana, Dario, Luo, Xiaodong, Valestrand, Randi, Nævdal, Geir
Format: Article
Language:English
Subjects:
Assimilation
Collapse
Data reduction
Datasets
Earth and Environmental Science
Earth Sciences
Geotechnical Engineering & Applied Earth Sciences
Hydrogeology
Iterative methods
Localization
Mathematical Modeling and Industrial Mathematics
Methodology
Methods
Noise reduction
Original Paper
Robustness
Scaling
Seismic data
Seismic properties
Soil Science & Conservation
Workflow
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Summary:Automatic history matching using production and seismic data is still challenging due to the size of seismic datasets. The most severe problem, when applying ensemble-based methods for assimilating large datasets, is that the uncertainty is usually underestimated due to the limited number of models in the ensemble compared with the dimension of the data, which inevitably leads to an ensemble collapse. Localization and data reduction methods are promising approaches mitigating this problem. In this paper, we present a new robust and flexible workflow for assimilating seismic attributes and production data. The methodology is based on sparse representation of the seismic data, using methods developed for image denoising. We propose to assimilate production and seismic data simultaneously, and to ensure equal weight on these data types, we apply scaling based on the initial data match. Further, a newly developed flexible correlation-based localization technique is used for both data types. The workflow is successfully implemented for the released Norne benchmark dataset, and an iterative ensemble smoother is used for the simultaneous assimilation of production and seismic data. We show that the methodology is robust and ensemble collapse is avoided. Furthermore, the proposed workflow is flexible, as it can be applied to seismic data or inverted seismic properties, and the methodology requires only moderate computer memory. The results show that through this method, we can successfully reduce the data mismatch for both production data and seismic data.
ISSN:1420-0597
1573-1499
DOI:10.1007/s10596-019-09900-0