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Physics-informed machine learning-based real-time long-horizon temperature fields prediction in metallic additive manufacturing

Mingxuan Tian, Haochen Mu, Tao Liu, Mengjiao Li, Donghong Ding, Jianping Zhao

2025Communications Engineering11 citationsDOIOpen Access PDF

Abstract

Real-time long-horizon temperature prediction in wire arc additive manufacturing is critical for process control and quality assurance. However, finite element methods are computationally expensive, and the existing data-driven models suffer from error accumulation and poor adaptability. Here we propose a physics-informed geometric recurrent neural network that integrates geometric characteristics and physical constraints, captures spatiotemporal characteristics via convolutional long short-term memory cells, and enforces physical consistency through hard-encoding initial/boundary conditions and physics-informed loss function. The model can predict the temperature field for future 1.25 s based on current 1.25 s data, and has also been evaluated for more long-horizon predictions. Transfer learning was used to enhance the model’s efficiency in practical applications. Results demonstrate that the proposed model achieves 4.5−13.9% maximum prediction error in simulations and experimental data. Including geometric characteristics and physical information reduces maximum error by about 1%, while the integrated model lowers it by 4%. Furthermore, transfer learning reduces the training time by approximately 50% while achieving the same loss level. Real-time long-horizon temperature prediction in metal additive manufacturing is critical for process control and quality assurance. Mingxuan Tian and colleagues propose a physics-informed machine learning model to predict temperature field for future 1.25 s.

Topics & Concepts

Artificial neural networkConsistency (knowledge bases)Process (computing)Convolutional neural networkComputer scienceFinite element methodAlgorithmField (mathematics)Quality (philosophy)Approximation errorTransfer of learningProcess controlHeat transferTemperature measurementTransfer (computing)Solid modelingCurrent (fluid)Artificial intelligenceProcess modelingControl theory (sociology)Transfer functionMean squared prediction errorMathematical modelGeometric modelingGeometric shapeData modelingAdditive Manufacturing Materials and ProcessesWelding Techniques and Residual StressesMachine Learning in Materials Science