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Main Authors: Yu, Ruoxi, Charreyron, Samuel L., Boehler, Quentin, Weibel, Cameron, Poon, Carmen C. Y., Nelson, Bradley J.
Format: Preprint
Published: 2019
Subjects:
Online Access:https://arxiv.org/abs/1909.12028
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author Yu, Ruoxi
Charreyron, Samuel L.
Boehler, Quentin
Weibel, Cameron
Poon, Carmen C. Y.
Nelson, Bradley J.
author_facet Yu, Ruoxi
Charreyron, Samuel L.
Boehler, Quentin
Weibel, Cameron
Poon, Carmen C. Y.
Nelson, Bradley J.
contents Electromagnetic Navigation Systems (eMNS) can be used to control a variety of multiscale devices within the human body for remote surgery. Accurate modeling of the magnetic fields generated by the electromagnets of an eMNS is crucial for the precise control of these devices. Existing methods assume a linear behavior of these systems, leading to significant modeling errors within nonlinear regions exhibited at higher magnetic fields. In this paper, we use a random forest (RF) and an artificial neural network (ANN) to model the nonlinear behavior of the magnetic fields generated by an eMNS. Both machine learning methods outperformed the state-of-the-art linear multipole electromagnet method (LMEM). The RF and the ANN model reduced the root mean squared error of the LMEM when predicting the field magnitude by around 40% and 80%, respectively, over the entire current range of the eMNS. At high current regions, especially between 30 and 35 A, the field-magnitude RMSE improvement of the ANN model over the LMEM was over 35 mT. This study demonstrates the feasibility of using machine learning methods to model an eMNS for medical applications, and its ability to account for complex nonlinear behavior at high currents. The use of machine learning thus shows promise for improving surgical procedures that use magnetic navigation.
format Preprint
id arxiv_https___arxiv_org_abs_1909_12028
institution arXiv
publishDate 2019
record_format arxiv
spellingShingle Modeling Electromagnetic Navigation Systems for Medical Applications using Random Forests and Artificial Neural Networks
Yu, Ruoxi
Charreyron, Samuel L.
Boehler, Quentin
Weibel, Cameron
Poon, Carmen C. Y.
Nelson, Bradley J.
Systems and Control
Machine Learning
Electromagnetic Navigation Systems (eMNS) can be used to control a variety of multiscale devices within the human body for remote surgery. Accurate modeling of the magnetic fields generated by the electromagnets of an eMNS is crucial for the precise control of these devices. Existing methods assume a linear behavior of these systems, leading to significant modeling errors within nonlinear regions exhibited at higher magnetic fields. In this paper, we use a random forest (RF) and an artificial neural network (ANN) to model the nonlinear behavior of the magnetic fields generated by an eMNS. Both machine learning methods outperformed the state-of-the-art linear multipole electromagnet method (LMEM). The RF and the ANN model reduced the root mean squared error of the LMEM when predicting the field magnitude by around 40% and 80%, respectively, over the entire current range of the eMNS. At high current regions, especially between 30 and 35 A, the field-magnitude RMSE improvement of the ANN model over the LMEM was over 35 mT. This study demonstrates the feasibility of using machine learning methods to model an eMNS for medical applications, and its ability to account for complex nonlinear behavior at high currents. The use of machine learning thus shows promise for improving surgical procedures that use magnetic navigation.
title Modeling Electromagnetic Navigation Systems for Medical Applications using Random Forests and Artificial Neural Networks
topic Systems and Control
Machine Learning
url https://arxiv.org/abs/1909.12028