Simulation-aided workflow toward dynamic fluid phantoms for impedance plethysmography

Johannes Hoffmann; Larissa Fueller; Roman Kusche; Sebastian Zaunseder

doi:10.18416/AUTOMED.2026.2492

Proceedings on Automation in Medical Engineering
Vol. 3 No. 1 (2026): Proc AUTOMED
https://doi.org/10.18416/AUTOMED.2026.2492

18th Interdisciplinary AUTOMED Symposium in Collaboration with the TC Medical Robotics, 2492

Simulation-aided workflow toward dynamic fluid phantoms for impedance plethysmography

Johannes Hoffmann (Chair for Diagnostic Sensing, University of Augsburg), Larissa Fueller (Chair for Diagnostic Sensing, University of Augsburg), Roman Kusche (Faculty of Engineering, Media, and Information Technology, HAW Hamburg), Sebastian Zaunseder (Chair for Diagnostic Sensing, University of Augsburg)

This work is licensed under a Creative Commons Attribution 4.0 International License.

Abstract

Impedance plethysmography (IPG) is recently gaining traction as a non-invasive sensing technique suitable for wearable devices, such as smartwatches. In this context, dynamic fluid phantoms can provide well-defined test scenarios to enable algorithm design and training. We outline the initial steps of our phantom design process, which relies on a combination of simulation studies and experiments. We conducted measurements in saline solutions and implemented a corresponding simulation of a time-varying pulse wave. Our overarching goal is the integration of an IPG component into a multi-modal dynamic fluid phantom.

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