Litcius/Paper detail

Gas-liquid flow regimes identification using non-intrusive Doppler ultrasonic sensor and convolutional recurrent neural networks in an s-shaped riser

Boyu Kuang, Somtochukwu Godfrey Nnabuife, Shuang Sun, James F. Whidborne, Zeeshan A. Rana

2022Digital Chemical Engineering23 citationsDOIOpen Access PDF

Abstract

The problem of gas-liquid (two-phase) flow regime identification in an S-shaped riser using an ultrasonic sensor and convolutional recurrent neural networks (CRNN) is addressed. This research systematically evaluates three different schemes with four CRNN-based classifiers over fourteen experiments. Four metrics are used as the evaluation criteria: categorical accuracy, categorical cross-entropy, mean square error (MSE), and computation graph complexity. Compared with existing results, a compatible performance is achieved while considerably reducing the model complexity. The testing and validation accuracies were 98.13% and 98.06%, while the complexity decreased by 98.4% (only 117,702 parameters). The proposed approach is i) accurate, low complexity, and non-intrusive and hence suitable for industry, and ii) could provide a benchmark for flow regime identification.

Topics & Concepts

Benchmark (surveying)Categorical variableComputer scienceIdentification (biology)Computational complexity theoryComputationRecurrent neural networkConvolutional neural networkUltrasonic sensorGraphAlgorithmArtificial intelligencePattern recognition (psychology)Artificial neural networkMachine learningAcousticsTheoretical computer sciencePhysicsGeographyBiologyBotanyGeodesyFlow Measurement and AnalysisFluid Dynamics and MixingFault Detection and Control Systems