Source Localization for Electrohydraulic Shockwave Devices

Hannah Janout; Stephan Winkler; Cyrill Slezak

Source Localization for Electrohydraulic Shockwave Devices

Hannah Janout
, Stephan Winkler
, Cyrill Slezak

Publikation: Konferenzbeitrag › Papier › Begutachtung

Abstract

Extracorporeal shockwave therapy (ESWT) uses high-energy, short-duration acoustic waves to stimulate tissue repair. These waves can be generated in electrohydraulic (EH) devices by a high-voltage discharge across a two-electrode spark-gap. Despite the fixed position of the electrodes, the origin of the shockwave can vary slightly, and the impact of this variability on resulting shockwaves and treatments remains unknown.

This paper proposes a workflow to optimize the placement of 4 independent hydrophones for the source multilateration using an evolution strategy. The results of the evolution strategy yield a best configuration deviating from the origin by only 0.0152 mm while meeting the experimental constraints. The most effective solution will be the basis for the design of a 3D print sensor holder, supporting further investigation into the EH origin position and resulting shockwaves. Further research will focus on adjusting the evolution strategy to account for all constraints and enhance its robustness.

Originalsprache	Englisch
Publikationsstatus	Veröffentlicht - 2025
Veranstaltung	EUROCAST 2024: 19th International Conference on Computer Aided Systems Theory - Museo Elder de la Ciencia y la Tecnología, Las Palmas de Gran Canaria, Spanien Dauer: 25 Feb. 2024 → 1 März 2024 https://eurocast2024.fulp.ulpgc.es

Konferenz

Konferenz	EUROCAST 2024
Land/Gebiet	Spanien
Ort	Las Palmas de Gran Canaria
Zeitraum	25.02.2024 → 01.03.2024
Internetadresse	https://eurocast2024.fulp.ulpgc.es

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title = "Source Localization for Electrohydraulic Shockwave Devices",

abstract = "Extracorporeal shockwave therapy (ESWT) uses high-energy, short-duration acoustic waves to stimulate tissue repair. These waves can be generated in electrohydraulic (EH) devices by a high-voltage discharge across a two-electrode spark-gap. Despite the fixed position of the electrodes, the origin of the shockwave can vary slightly, and the impact of this variability on resulting shockwaves and treatments remains unknown. This paper proposes a workflow to optimize the placement of 4 independent hydrophones for the source multilateration using an evolution strategy. The results of the evolution strategy yield a best configuration deviating from the origin by only 0.0152 mm while meeting the experimental constraints. The most effective solution will be the basis for the design of a 3D print sensor holder, supporting further investigation into the EH origin position and resulting shockwaves. Further research will focus on adjusting the evolution strategy to account for all constraints and enhance its robustness. ",

author = "Hannah Janout and Stephan Winkler and Cyrill Slezak",

year = "2025",

language = "English",

note = "EUROCAST 2024 : 19th International Conference on Computer Aided Systems Theory ; Conference date: 25-02-2024 Through 01-03-2024",

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TY - CONF

T1 - Source Localization for Electrohydraulic Shockwave Devices

AU - Janout, Hannah

AU - Winkler, Stephan

AU - Slezak, Cyrill

PY - 2025

Y1 - 2025

N2 - Extracorporeal shockwave therapy (ESWT) uses high-energy, short-duration acoustic waves to stimulate tissue repair. These waves can be generated in electrohydraulic (EH) devices by a high-voltage discharge across a two-electrode spark-gap. Despite the fixed position of the electrodes, the origin of the shockwave can vary slightly, and the impact of this variability on resulting shockwaves and treatments remains unknown. This paper proposes a workflow to optimize the placement of 4 independent hydrophones for the source multilateration using an evolution strategy. The results of the evolution strategy yield a best configuration deviating from the origin by only 0.0152 mm while meeting the experimental constraints. The most effective solution will be the basis for the design of a 3D print sensor holder, supporting further investigation into the EH origin position and resulting shockwaves. Further research will focus on adjusting the evolution strategy to account for all constraints and enhance its robustness.

AB - Extracorporeal shockwave therapy (ESWT) uses high-energy, short-duration acoustic waves to stimulate tissue repair. These waves can be generated in electrohydraulic (EH) devices by a high-voltage discharge across a two-electrode spark-gap. Despite the fixed position of the electrodes, the origin of the shockwave can vary slightly, and the impact of this variability on resulting shockwaves and treatments remains unknown. This paper proposes a workflow to optimize the placement of 4 independent hydrophones for the source multilateration using an evolution strategy. The results of the evolution strategy yield a best configuration deviating from the origin by only 0.0152 mm while meeting the experimental constraints. The most effective solution will be the basis for the design of a 3D print sensor holder, supporting further investigation into the EH origin position and resulting shockwaves. Further research will focus on adjusting the evolution strategy to account for all constraints and enhance its robustness.

M3 - Paper

T2 - EUROCAST 2024

Y2 - 25 February 2024 through 1 March 2024

ER -

Source Localization for Electrohydraulic Shockwave Devices

Abstract

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