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Main Authors: Clinkinbeard, Nicholus R., Sehlin, Justin, Bhatti, Meharpal Singh, McNamarra, Marilyn, Montazami, Reza, Hashemi, Nicole N.
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2412.08822
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author Clinkinbeard, Nicholus R.
Sehlin, Justin
Bhatti, Meharpal Singh
McNamarra, Marilyn
Montazami, Reza
Hashemi, Nicole N.
author_facet Clinkinbeard, Nicholus R.
Sehlin, Justin
Bhatti, Meharpal Singh
McNamarra, Marilyn
Montazami, Reza
Hashemi, Nicole N.
contents Selection of solution concentrations and flow rates for the fabrication of microfibers using a microfluidic device is a largely empirical endeavor of trial-and-error, largely due to the difficulty of modeling such a multiphysics process. Machine learning, including deep neural networks, provides the potential for allowing the determination of flow rates and solution characteristics by using past fabrication data to train and validate a model. Unfortunately, microfluidics suffers from low amounts of data, which can lead to inaccuracies and overtraining. To reduce the errors inherent with developing predictive and design models using a deep neural network, two approaches are investigated: dataset expansion using the statistical properties of available samples and model enhancement through introduction of physics-related parameters, specifically dimensionless numbers such as the Reynolds, capillary, Weber, and Peclet numbers. Results show that introduction of these parameters provides enhanced predictive capability leading to increased accuracy, while no such improvements are yet observed for design parameter selection.
format Preprint
id arxiv_https___arxiv_org_abs_2412_08822
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Predicting Performance of Microfluidic-Based Alginate Microfibers with Feature-Supplemented Deep Neural Networks
Clinkinbeard, Nicholus R.
Sehlin, Justin
Bhatti, Meharpal Singh
McNamarra, Marilyn
Montazami, Reza
Hashemi, Nicole N.
Fluid Dynamics
Materials Science
Selection of solution concentrations and flow rates for the fabrication of microfibers using a microfluidic device is a largely empirical endeavor of trial-and-error, largely due to the difficulty of modeling such a multiphysics process. Machine learning, including deep neural networks, provides the potential for allowing the determination of flow rates and solution characteristics by using past fabrication data to train and validate a model. Unfortunately, microfluidics suffers from low amounts of data, which can lead to inaccuracies and overtraining. To reduce the errors inherent with developing predictive and design models using a deep neural network, two approaches are investigated: dataset expansion using the statistical properties of available samples and model enhancement through introduction of physics-related parameters, specifically dimensionless numbers such as the Reynolds, capillary, Weber, and Peclet numbers. Results show that introduction of these parameters provides enhanced predictive capability leading to increased accuracy, while no such improvements are yet observed for design parameter selection.
title Predicting Performance of Microfluidic-Based Alginate Microfibers with Feature-Supplemented Deep Neural Networks
topic Fluid Dynamics
Materials Science
url https://arxiv.org/abs/2412.08822