Reservoir parameters determination using artificial neural networks: Ras Fanar field, Gulf of Suez, Egypt |
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Authors: | Aref Lashin Samy Serag El Din |
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Institution: | 1. College of Science, Geology and Geophysics Department, King Saud University, P. O. Box 2455, Riyadh, 11451, Saudi Arabia 2. Faculty of Science, Geology Department, Benha University, P.O. Box 13518, Benha, Egypt 3. Saudi Geological Survey (SGS) Research Chair, King Saud University, Riyadh, Saudi Arabia 4. Abu Dhabi Company for Onshore Oil Operation (ADCO), Abu Dhabi, United Arab Emirates
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Abstract: | Ras Fanar field is one of the largest oil-bearing carbonate reservoirs in the Gulf of Suez. The field produces from the Middle Miocene Nullipore carbonate reservoir, which consists mainly of algal-rich dolomite and dolomitic limestone rocks, and range in thickness between 400 and 980 ft. All porosity types within the Nullipore rocks have been modified by diagenetic processes such as dolomitization, leaching, and cementation; hence, the difficulty arise in the accurate determination of certain petrophysical parameters, such as porosity and permeability, using logging data only. In this study, artificial neural networks (ANN) are used to estimate and predict the most important petrophysical parameters of Nullipore reservoir based on well logging data and available core plug analyses. The different petrophysical parameters are first calculated from conventional logging and measured core analyses. It is found that pore spaces are uniform all over the reservoirs (17–23%), while hydrocarbon content constitutes more than 55% and represented mainly by oil with little saturations of secondary gasses. A regular regression analysis is carried out over the calculated and measured parameters, especially porosity and permeability. Fair to good correlation (R <65%) is recognized between both types of datasets. A predictive ANN module is applied using a simple forward backpropagation technique using the information gathered from the conventional and measured analyses. The predicted petrophysical parameters are found to be much more accurate if compared with the parameters calculated from conventional logging analyses. The statistics of the predicted parameters relative to the measured data, show lower sum error (<0.17%) and higher correlation coefficient (R >80%) indicating that good matching and correlation is achieved between the measured and predicted parameters. This well-learned artificial neural network can be further applied as a predictive module in other wells in Ras Fanar field where core data are unavailable. |
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