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Wang, S., Qin, C., Feng, Q., et al. (2021). A framework for predicting the production performance of unconventional resources using deep learning. Applied Energy, 295, 117016.Search in Google Scholar
Saputra, W., Kirati, W., & Patzek, T. (2021). Forecast of economic tight oil and gas production in Permian Basin. Energies, 15(1), 43-53.Search in Google Scholar
Dheyauldeen, A., Al-Fatlawi, O., & Hossain, M. M. (2021). Incremental and acceleration production estimation and their effect on optimization of well infill locations in tight gas reservoirs. Journal of Petroleum Exploration and Production Technology, 11(6), 2449-2480.Search in Google Scholar
Childers, D. R., & Wu, X. (2020). Forecasting shale gas performance using the Connected Reservoir Storage Model. Journal of Natural Gas Science and Engineering, 82, 103499.Search in Google Scholar
Allugunti, V. R. (2022). A machine learning model for skin disease classification using convolution neural network. International Journal of Computing, Programming and Database Management, 3(1), 141-147.Search in Google Scholar
Wang, S., Chen, S. (2019). Application of the long short-term memory networks for well-testing data interpretation in tight reservoirs. Journal of Petroleum Science and Engineering, 183, 106391.Search in Google Scholar
Slot, R. M. M., Sørensen, J. D., Sudret, B., et al. (2020). Surrogate model uncertainty in wind turbine reliability assessment. Renewable Energy, 151, 1150-1162.Search in Google Scholar
Malik, S., & Kim, D. H. (2018). Prediction-learning algorithm for efficient energy consumption in smart buildings based on particle regeneration and velocity boost in particle swarm optimization neural networks. Energies, 11(5), 1289-1299.Search in Google Scholar
Emmanuel, I., Adeolu, A., & Adebanjo, F. O. (2020). Prediction of Asphaltene Precipitation During Gas Injection Using Hybrid Genetic Algorithm and Particle Swarm Optimisation. American Journal of Applied and Industrial Chemistry, 4(2), 21-30.Search in Google Scholar
Chao, Z., Wang, M., Sun, Y., et al. (2022). Predicting stress-dependent gas permeability of cement mortar with different relative moisture contents based on hybrid ensemble artificial intelligence algorithms. Construction and Building Materials, 348, 128660.Search in Google Scholar
Chen, H., Zhang, C., Jia, N., et al. (2021). A machine learning model for predicting the minimum miscibility pressure of CO2 and crude oil system based on a support vector machine algorithm approach. Fuel, 290, 120048.Search in Google Scholar
Otchere, D. A., Ganat, T. O. A., Gholami, R., et al. (2021). Application of supervised machine learning paradigms in the prediction of petroleum reservoir properties: Comparative analysis of ANN and SVM models. Journal of Petroleum Science and Engineering, 200, 108182.Search in Google Scholar
Ahmadi, M. A., & Chen, Z. (2019). Comparison of machine learning methods for estimating permeability and porosity of oil reservoirs via petro-physical logs. Petroleum, 5(3), 271-284.Search in Google Scholar
Okon, A. N., Adewole, S. E., & Uguma, E. M. (2021). Artificial neural network model for reservoir petrophysical properties: porosity, permeability and water saturation prediction. Modeling Earth Systems and Environment, 7(4), 2373-2390.Search in Google Scholar
Bai, T., & Tahmasebi, P. (2021). Efficient and data-driven prediction of water breakthrough in subsurface systems using deep long short-term memory machine learning. Computational Geosciences, 25(1), 285-297.Search in Google Scholar
Kalantariasl, A., Yazdanpanah, A., Ghanat-pisheh, E., et al. (2021). Prediction of sub-critical two-phase flow through wellhead chokes of gas condensate wells using PSO-LSSVM method. Upstream Oil and Gas Technology, 7, 100057.Search in Google Scholar
Ahmadi, M. A., Hasanvand, M. Z., & Bahadori, A. (2017). A least-squares support vector machine approach to predict temperature drop accompanying a given pressure drop for the natural gas production and processing systems. International Journal of Ambient Energy, 38(2), 122-129.Search in Google Scholar
Shahamat, M. S., Mattar, L., & Aguilera, R. (2015). Analysis of decline curves on the basis of beta-derivative. SPE Reservoir Evaluation & Engineering, 18(02), 214-227.Search in Google Scholar
Vickers, A. J., van Calster, B., & Steyerberg, E. W. (2019). A simple, step-by-step guide to interpreting decision curve analysis. Diagnostic and prognostic research, 3(1), 1-8.Search in Google Scholar
Xu, G., Yin, H., Yuan, H., et al. (2020). Decline curve analysis for multiple-fractured horizontal wells in tight oil reservoirs. Advances in Geo-Energy Research, 4(3), 296-304.Search in Google Scholar
Qin, J., Cheng, S., He, Y., et al. (2019). Decline curve analysis of fractured horizontal wells through segmented fracture model. Journal of Energy Resources Technology, 141(1), 012903.1-012903.7.Search in Google Scholar
Zang, J., Ge, Y., & Wang, K. (2020). The principal permeability tensor of inclined coalbeds during pore pressure depletion under uniaxial strain conditions: developing a mathematical model, evaluating the influences of featured parameters, and upscaling for CBM recovery. Journal of Natural Gas Science and Engineering, 74, 103099.Search in Google Scholar
Elbes, M., Alzubi, S., Kanan, T., et al. (2019). A survey on particle swarm optimization with emphasis on engineering and network applications. Evolutionary Intelligence, 12(2), 113-129.Search in Google Scholar
