Volume-6 Issue-1, May 2026 – Indian Journal of Petroleum Engineering (IJPE) https://www.ijpe.latticescipub.com Exploring Innovation | ISSN: 2582-9297 (Online) | A Periodical Journal | Reg. No: C/1383209 | Published by Lattice Science Publication (LSP) Sat, 30 May 2026 03:38:17 +0000 en-US hourly 1 https://wordpress.org/?v=7.0 https://www.ijpe.latticescipub.com/wp-content/uploads/2021/10/cropped-IJPE-Logo-WS-32x32.png Volume-6 Issue-1, May 2026 – Indian Journal of Petroleum Engineering (IJPE) https://www.ijpe.latticescipub.com 32 32 A192406010526 https://www.ijpe.latticescipub.com/portfolio-item/a192406010526/ Tue, 26 May 2026 10:21:32 +0000 https://www.ijpe.latticescipub.com/?post_type=portfolio&p=1100 The Indian Journal of Petroleum Engineering (IJPE) has ISSN 2582-9297 (online), an open-access, peer-reviewed, periodical half-yearly international journal, which is published by Lattice Science Publication (LSP) in May and November. The journal aims to publish high-quality peer–reviewed original articles in the area of Petroleum Engineering that covers Origin and Accumulation of Petroleum and Natural Gas, Petroleum Geochemistry, Reservoir Engineering, Reservoir Simulation, Rock Mechanics, Petrophysics, Pore-Level Phenomena, Well Logging, Testing and Evaluation, Mathematical Modelling, Enhanced Oil and Gas, Recovery, Petroleum Geology, Compaction/Diagenesis, Petroleum Economics, Drilling and Drilling Fluids, Thermodynamics and Phase Behaviour, Fluid Mechanics, Multi-Phase Flow in Porous Media, Production Engineering, Formation Evaluation, Exploration Methods, Co2 Sequestration in Geological Formations/Sub-Surface, Management and Development of Unconventional Resources Such as Heavy Oil and Bitumen, Tight Oil and Liquid Rich Shales Production of Hydrocarbons, Formation Evaluation (Well Logging), Drilling and Economics, Oil Refining, Synthetic Fuel Technologies, Oil Shale Technology. #Origin and Accumulation of Petroleum and Natural Gas #Petroleum Geochemistry #Reservoir Engineering #Reservoir Simulation #Rock Mechanics #Petrophysics #Pore-Level Phenomena #Well Logging #Testing and Evaluation #Mathematical Modelling #Enhanced Oil and Gas Recovery #Petroleum Geology #Compaction/Diagenesis #Petroleum Economics #Drilling and Drilling Fluids #Thermodynamics and Phase Behaviour #Fluid Mechanics #Multi-Phase Flow in Porous Media #Production Engineering #Formation Evaluation #Exploration Methods #Co2 Sequestration in Geological Formations/Sub-Surface #Management and Development of Unconventional Resources Such as Heavy Oil and Bitumen #Tight Oil and Liquid Rich Shales #Production of Hydrocarbons #Petroleum Geology #Formation Evaluation (Well Logging), Drilling and Economics #Oil Refining #Synthetic Fuel Technologies #Oil Shale Technology #Reservoir Simulation #PhD ademic #Scopus #SCI #LatticeScience #Springer, #ScienceDirect #IEEE #Mendeley #Research #Scholarship #UGC #SSRN #LatticeScience #ESCI #Science #Journal #Conference #SSRN #PubLons #PhD #Academic #Scopus #SCI #LatticeScience #Springer, #ScienceDirect #IEEE #Mendeley #Research #Scholarship #UGC #SSRN #LatticeScience #ESCI #Science #Journal #Conference #SSRN #PubLons

Accurate estimation of liquid rate, gas rate, and water cut is essential for effective production surveillance, reservoir management, and operational decision-making in oil and gas assets. In most producing fields, direct production measurements are obtained through periodic well tests or selectively deployed multiphase flow meters, resulting in sparse temporal resolution, delayed detection of production changes, and limited field-wide visibility. Physics-based production models provide valuable engineering insight but require frequent calibration and often struggle to maintain accuracy under transient operating conditions and evolving reservoir behavior. These limitations motivate the use of data-driven approaches that leverage existing field instrumentation to deliver continuous production estimates. This paper presents a machine learning–based Virtual Flow Meter (VFM) for continuous estimation of oil, gas, and water production rates using routinely available operational measurements. High-frequency field data, including pressures, temperatures, choke settings, and, where applicable, lift-gas injection rates, are temporally aligned with historical well-test and laboratory measurements to construct reliable training datasets. Independent regression models are developed for oil, gas, and water rates, allowing each model to capture phasespecific sensitivities while maintaining physical consistency and avoiding reliance on explicit flow-regime identification or mechanistic multiphase correlations. The proposed VFM is deployed end-to-end on a commercial data analytics platform, enabling continuous ingestion of sensor data, real-time inference, performance monitoring, and periodic retraining. Model validation using historical field data demonstrates strong agreement between predicted and reference production values across all phases, indicating that the data- driven VFM provides reliable, meter-like production estimates. The results show that continuous production surveillance can be achieved without additional hardware or instrumentation, offering a scalable and cost-effective solution for large well portfolios. This approach supports proactive operational decision- making and enhances production visibility across modern oil and gas assets.

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]]> The Indian Journal of Petroleum Engineering (IJPE) has ISSN 2582-9297 (online), an open-access, peer-reviewed, periodical half-yearly international journal, which is published by Lattice Science Publication (LSP) in May and November. The journal aims to publish high-quality peer–reviewed original articles in the area of Petroleum Engineering that covers Origin and Accumulation of Petroleum and Natural Gas, Petroleum Geochemistry, Reservoir Engineering, Reservoir Simulation, Rock Mechanics, Petrophysics, Pore-Level Phenomena, Well Logging, Testing and Evaluation, Mathematical Modelling, Enhanced Oil and Gas, Recovery, Petroleum Geology, Compaction/Diagenesis, Petroleum Economics, Drilling and Drilling Fluids, Thermodynamics and Phase Behaviour, Fluid Mechanics, Multi-Phase Flow in Porous Media, Production Engineering, Formation Evaluation, Exploration Methods, Co2 Sequestration in Geological Formations/Sub-Surface, Management and Development of Unconventional Resources Such as Heavy Oil and Bitumen, Tight Oil and Liquid Rich Shales Production of Hydrocarbons, Formation Evaluation (Well Logging), Drilling and Economics, Oil Refining, Synthetic Fuel Technologies, Oil Shale Technology. #Origin and Accumulation of Petroleum and Natural Gas #Petroleum Geochemistry #Reservoir Engineering #Reservoir Simulation #Rock Mechanics #Petrophysics #Pore-Level Phenomena #Well Logging #Testing and Evaluation #Mathematical Modelling #Enhanced Oil and Gas Recovery #Petroleum Geology #Compaction/Diagenesis #Petroleum Economics #Drilling and Drilling Fluids #Thermodynamics and Phase Behaviour #Fluid Mechanics #Multi-Phase Flow in Porous Media #Production Engineering #Formation Evaluation #Exploration Methods #Co2 Sequestration in Geological Formations/Sub-Surface #Management and Development of Unconventional Resources Such as Heavy Oil and Bitumen #Tight Oil and Liquid Rich Shales #Production of Hydrocarbons #Petroleum Geology #Formation Evaluation (Well Logging), Drilling and Economics #Oil Refining #Synthetic Fuel Technologies #Oil Shale Technology #Reservoir Simulation #PhD ademic #Scopus #SCI #LatticeScience #Springer, #ScienceDirect #IEEE #Mendeley #Research #Scholarship #UGC #SSRN #LatticeScience #ESCI #Science #Journal #Conference #SSRN #PubLons #PhD #Academic #Scopus #SCI #LatticeScience #Springer, #ScienceDirect #IEEE #Mendeley #Research #Scholarship #UGC #SSRN #LatticeScience #ESCI #Science #Journal #Conference #SSRN #PubLons

A Machine Learning–Based Virtual Flow Meter for Continuous Estimation of Well Production RatesCROSSMARK Color horizontal
Mohammad Amir Ashraff

Mohammad Amir Ashraff, Department of Data Science and Advanced Analytics, Hyderabad (Telangana), India.

Manuscript received on 09 January 2026 | First Revised Manuscript received on 19 January 2026 | Second Revised Manuscript received on 16 April 2026 | Manuscript Accepted on 15 May 2026 | Manuscript published on 30 May 2026 | PP: 1-9 | Volume-6 Issue-1 May 2026 | Retrieval Number: 100.1/ijpe.A192406010526 | DOI: 10.54105/ijpe.A1924.06010526

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© The Authors. Published by Lattice Science Publication (LSP). This is an open-access article under the CC-BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/)

Abstract: Accurate estimation of liquid rate, gas rate, and water cut is essential for effective production surveillance, reservoir management, and operational decision-making in oil and gas assets. In most producing fields, direct production measurements are obtained through periodic well tests or selectively deployed multiphase flow meters, resulting in sparse temporal resolution, delayed detection of production changes, and limited field-wide visibility. Physics-based production models provide valuable engineering insight but require frequent calibration and often struggle to maintain accuracy under transient operating conditions and evolving reservoir behavior. These limitations motivate the use of data-driven approaches that leverage existing field instrumentation to deliver continuous production estimates. This paper presents a machine learning–based Virtual Flow Meter (VFM) for continuous estimation of oil, gas, and water production rates using routinely available operational measurements. High-frequency field data, including pressures, temperatures, choke settings, and, where applicable, lift-gas injection rates, are temporally aligned with historical well-test and laboratory measurements to construct reliable training datasets. Independent regression models are developed for oil, gas, and water rates, allowing each model to capture phasespecific sensitivities while maintaining physical consistency and avoiding reliance on explicit flow-regime identification or mechanistic multiphase correlations. The proposed VFM is deployed end-to-end on a commercial data analytics platform, enabling continuous ingestion of sensor data, real-time inference, performance monitoring, and periodic retraining. Model validation using historical field data demonstrates strong agreement between predicted and reference production values across all phases, indicating that the data- driven VFM provides reliable, meter-like production estimates. The results show that continuous production surveillance can be achieved without additional hardware or instrumentation, offering a scalable and cost-effective solution for large well portfolios. This approach supports proactive operational decision- making and enhances production visibility across modern oil and gas assets.

Keywords: Virtual Flow Meter, Machine Learning, Well Rate Estimation, Multiphase Flow, Production Surveillance.
Scope of the Article: Drilling Engineering

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