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Hauptverfasser: Ward-Bond, Jesse, Mashadian, Ali, Chan, Timothy C. Y., Young, Edmond W. K.
Format: Preprint
Veröffentlicht: 2026
Schlagworte:
Online-Zugang:https://arxiv.org/abs/2605.08109
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author Ward-Bond, Jesse
Mashadian, Ali
Chan, Timothy C. Y.
Young, Edmond W. K.
author_facet Ward-Bond, Jesse
Mashadian, Ali
Chan, Timothy C. Y.
Young, Edmond W. K.
contents Inertial microfluidic devices (IMDs) offer low-cost, high-throughput alternative techniques for many traditional particle- (or cell-) manipulation tasks, but simulating them requires being able to predict particle migration, and thus particle lift forces, under a variety of possible channel geometries. Recent work has demonstrated that machine learning models can be used to drastically speed up these numerical simulations, but doing so required training individual models for every unique channel cross-section type (e.g., rectangular, triangular) -- shifting the burden from the simulation step to the training step. In this paper, we develop a novel approach for predicting particle lift forces that contains no explicit geometric parameters. We train a neural network model using a new parameter set and show that while it performs comparably to existing models on channel geometries in the training set, it is able to generalize to unseen channel geometries far more effectively. We show that the lift force model developed herein can be easily transferred to particle tracing simulation software, where it is capable of predicting particle migration patterns consistent with the literature across a variety of channel designs.
format Preprint
id arxiv_https___arxiv_org_abs_2605_08109
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Geometry-free prediction of inertial lift forces in microfluidic devices using deep learning
Ward-Bond, Jesse
Mashadian, Ali
Chan, Timothy C. Y.
Young, Edmond W. K.
Machine Learning
Materials Science
Fluid Dynamics
Inertial microfluidic devices (IMDs) offer low-cost, high-throughput alternative techniques for many traditional particle- (or cell-) manipulation tasks, but simulating them requires being able to predict particle migration, and thus particle lift forces, under a variety of possible channel geometries. Recent work has demonstrated that machine learning models can be used to drastically speed up these numerical simulations, but doing so required training individual models for every unique channel cross-section type (e.g., rectangular, triangular) -- shifting the burden from the simulation step to the training step. In this paper, we develop a novel approach for predicting particle lift forces that contains no explicit geometric parameters. We train a neural network model using a new parameter set and show that while it performs comparably to existing models on channel geometries in the training set, it is able to generalize to unseen channel geometries far more effectively. We show that the lift force model developed herein can be easily transferred to particle tracing simulation software, where it is capable of predicting particle migration patterns consistent with the literature across a variety of channel designs.
title Geometry-free prediction of inertial lift forces in microfluidic devices using deep learning
topic Machine Learning
Materials Science
Fluid Dynamics
url https://arxiv.org/abs/2605.08109