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Temperature hotspot detection on printed circuit boards (PCBS) using ultrasonic guided waves—a machine learning approach

Temperature hotspot detection on printed circuit boards (PCBS) using ultrasonic guided waves—a machine learning approach
Temperature hotspot detection on printed circuit boards (PCBS) using ultrasonic guided waves—a machine learning approach
This paper addresses the challenging issue of achieving high spatial resolution in temperature monitoring of printed circuit boards (PCBs) without compromising the operation of electronic components. Traditional methods involving numerous dedicated sensors such as thermocouples are often intrusive and can impact electronic functionality. To overcome this, this study explores the application of ultrasonic guided waves, specifically utilising a limited number of cost-effective and unobtrusive PiezoelectricWafer Active Sensors (PWAS). Employing COMSOL multiphysics, wave propagation is simulated through a simplified PCB while systematically varying the temperature of both components and the board itself. Machine learning algorithms are used to identify hotspots at component positions using a minimal number of sensors. An accuracy of 97.6% is achieved with four sensors, decreasing to 88.1% when utilizing a single sensor in a pulse–echo configuration. The proposed methodology not only provides sufficient spatial resolution to identify hotspots but also offers a non-invasive and efficient solution. Such advancements are important for the future electrification of the aerospace and automotive industries in particular, as they contribute to condition-monitoring
technologies that are essential for ensuring the reliability and safety of electronic systems.
COMSOL, PWAS, condition monitoring, guided waves, printed circuit boards
1424-8220
Yule, Lawrence
87c4d44f-a50a-4ae4-8084-50de55b9a24c
Harris, Nicholas
237cfdbd-86e4-4025-869c-c85136f14dfd
Hill, Martyn
0cda65c8-a70f-476f-b126-d2c4460a253e
Zaghari, Bahareh
a0537db6-0dce-49a2-8103-0f4599ab5f6a
Grundy, Joanna
0bc72187-8dce-41fc-b809-93a6adbe0980
Yule, Lawrence
87c4d44f-a50a-4ae4-8084-50de55b9a24c
Harris, Nicholas
237cfdbd-86e4-4025-869c-c85136f14dfd
Hill, Martyn
0cda65c8-a70f-476f-b126-d2c4460a253e
Zaghari, Bahareh
a0537db6-0dce-49a2-8103-0f4599ab5f6a
Grundy, Joanna
0bc72187-8dce-41fc-b809-93a6adbe0980

Yule, Lawrence, Harris, Nicholas, Hill, Martyn, Zaghari, Bahareh and Grundy, Joanna (2024) Temperature hotspot detection on printed circuit boards (PCBS) using ultrasonic guided waves—a machine learning approach. Sensors, 24 (4), [1081]. (doi:10.3390/s24041081).

Record type: Article

Abstract

This paper addresses the challenging issue of achieving high spatial resolution in temperature monitoring of printed circuit boards (PCBs) without compromising the operation of electronic components. Traditional methods involving numerous dedicated sensors such as thermocouples are often intrusive and can impact electronic functionality. To overcome this, this study explores the application of ultrasonic guided waves, specifically utilising a limited number of cost-effective and unobtrusive PiezoelectricWafer Active Sensors (PWAS). Employing COMSOL multiphysics, wave propagation is simulated through a simplified PCB while systematically varying the temperature of both components and the board itself. Machine learning algorithms are used to identify hotspots at component positions using a minimal number of sensors. An accuracy of 97.6% is achieved with four sensors, decreasing to 88.1% when utilizing a single sensor in a pulse–echo configuration. The proposed methodology not only provides sufficient spatial resolution to identify hotspots but also offers a non-invasive and efficient solution. Such advancements are important for the future electrification of the aerospace and automotive industries in particular, as they contribute to condition-monitoring
technologies that are essential for ensuring the reliability and safety of electronic systems.

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More information

Accepted/In Press date: 1 February 2024
Published date: 7 February 2024
Keywords: COMSOL, PWAS, condition monitoring, guided waves, printed circuit boards
Learn more about Vision, Learning and Control research Learn more about Institute for Life Sciences research Learn more about Smart Electronic Materials and Systems research Learn more about Institute for Life Sciences research Learn more about Electrical Power Engineering research

Identifiers

Local EPrints ID: 490848
URI: http://eprints.soton.ac.uk/id/eprint/490848
DOI: doi:10.3390/s24041081
ISSN: 1424-8220
PURE UUID: 0807f9e0-0026-47c0-838a-041f9a20c4ac
ORCID for Lawrence Yule: ORCID iD orcid.org/0000-0002-0324-6642
ORCID for Nicholas Harris: ORCID iD orcid.org/0000-0003-4122-2219
ORCID for Martyn Hill: ORCID iD orcid.org/0000-0001-6448-9448
ORCID for Bahareh Zaghari: ORCID iD orcid.org/0000-0002-5600-4671
ORCID for Joanna Grundy: ORCID iD orcid.org/0000-0003-2583-5680

Catalogue record

Date deposited: 07 Jun 2024 16:34
Last modified: 21 Sep 2024 02:09

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Contributors

Author: Lawrence Yule ORCID iD
Author: Nicholas Harris ORCID iD
Author: Martyn Hill ORCID iD
Author: Bahareh Zaghari ORCID iD
Author: Joanna Grundy ORCID iD

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