Litcius/Paper detail

Physics-Informed Bayesian learning of electrohydrodynamic polymer jet printing dynamics

Athanasios Oikonomou, Θεόδωρος Λούτας, Dixia Fan, Alysia Garmulewicz, George Nounesis, Santanu Chaudhuri, Filippos Tourlomousis

2023Communications Engineering20 citationsDOIOpen Access PDF

Abstract

Abstract Calibration of highly dynamic multi-physics manufacturing processes such as electrohydrodynamics-based additive manufacturing (AM) technologies (E-jet printing) is still performed by labor-intensive trial-and-error practices. Such practices have hindered the broad adoption of these technologies, demanding a new paradigm of self-calibrating E-jet printing machines. Here we develop an end-to-end physics-informed Bayesian learning framework (GPJet) which can learn the jet process dynamics with minimum experimental cost. GPJet consists of three modules: the machine vision module, the physics-based modeling module, and the machine learning (ML) module. GPJet was tested on a virtual E-jet printing machine with in-process jet monitoring capabilities. Our results show that the Machine Vision module can extract high-fidelity jet features in real-time from video data using an automated parallelized computer vision workflow. The Machine Vision module, combined with the Physics-based modeling module, can also act as closed-loop sensory feedback to the Machine Learning module of high- and low-fidelity data. This work extends the application of intelligent AM machines to more complex working conditions while reducing cost and increasing computational efficiency.

Topics & Concepts

WorkflowMachine learningJet (fluid)Process (computing)Computer scienceArtificial intelligenceFidelityCalibrationMachine visionPhysicsEngineeringDatabaseAerospace engineeringOperating systemQuantum mechanicsTelecommunicationsElectrohydrodynamics and Fluid DynamicsCurrency Recognition and DetectionElectrowetting and Microfluidic Technologies