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Main Authors: Nyholm, Amanda, Arellano, Yessica, Liu, Jinyu, Krakowiak, Damian, Rossi, Pierluigi Salvo
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2601.12433
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author Nyholm, Amanda
Arellano, Yessica
Liu, Jinyu
Krakowiak, Damian
Rossi, Pierluigi Salvo
author_facet Nyholm, Amanda
Arellano, Yessica
Liu, Jinyu
Krakowiak, Damian
Rossi, Pierluigi Salvo
contents Reliable flow measurements are essential in many industries, but current instruments often fail to accurately estimate multiphase flows, which are frequently encountered in real-world operations. Combining machine learning (ML) algorithms with accurate single-phase flowmeters has therefore received extensive research attention in recent years. The Coriolis mass flowmeter is a widely used single-phase meter that provides direct mass flow measurements, which ML models can be trained to correct, thereby reducing measurement errors in multiphase conditions. This paper demonstrates that preserving temporal information significantly improves model performance in such scenarios. We compare a multilayer perceptron, a windowed multilayer perceptron, and a convolutional neural network (CNN) on three-phase air-water-oil flow data from 342 experiments. Whereas prior work typically compresses each experiment into a single averaged sample, we instead compute short-time averages from within each experiment and train models that preserve temporal information at several downsampling intervals. The CNN performed best at 0.25 Hz with approximately 95 % of relative errors below 13 %, a normalized root mean squared error of 0.03, and a mean absolute percentage error of approximately 4.3 %, clearly outperforming the best single-averaged model and demonstrating that short-time averaging within individual experiments is preferable. Results are consistent across multiple data splits and random seeds, demonstrating robustness.
format Preprint
id arxiv_https___arxiv_org_abs_2601_12433
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Temporal Data and Short-Time Averages Improve Multiphase Mass Flow Metering
Nyholm, Amanda
Arellano, Yessica
Liu, Jinyu
Krakowiak, Damian
Rossi, Pierluigi Salvo
Signal Processing
Machine Learning
Reliable flow measurements are essential in many industries, but current instruments often fail to accurately estimate multiphase flows, which are frequently encountered in real-world operations. Combining machine learning (ML) algorithms with accurate single-phase flowmeters has therefore received extensive research attention in recent years. The Coriolis mass flowmeter is a widely used single-phase meter that provides direct mass flow measurements, which ML models can be trained to correct, thereby reducing measurement errors in multiphase conditions. This paper demonstrates that preserving temporal information significantly improves model performance in such scenarios. We compare a multilayer perceptron, a windowed multilayer perceptron, and a convolutional neural network (CNN) on three-phase air-water-oil flow data from 342 experiments. Whereas prior work typically compresses each experiment into a single averaged sample, we instead compute short-time averages from within each experiment and train models that preserve temporal information at several downsampling intervals. The CNN performed best at 0.25 Hz with approximately 95 % of relative errors below 13 %, a normalized root mean squared error of 0.03, and a mean absolute percentage error of approximately 4.3 %, clearly outperforming the best single-averaged model and demonstrating that short-time averaging within individual experiments is preferable. Results are consistent across multiple data splits and random seeds, demonstrating robustness.
title Temporal Data and Short-Time Averages Improve Multiphase Mass Flow Metering
topic Signal Processing
Machine Learning
url https://arxiv.org/abs/2601.12433