Deep learning-based localization of electrical connector sockets for automated mating

Leopold Beck; Daniel Gebauer; Thomas Rauh; Jonas Dirr; Rüdiger Daub

doi:10.1007/s11740-024-01299-7

Deep learning-based localization of electrical connector sockets for automated mating

Leopold Beck, Daniel Gebauer, Thomas Rauh, Jonas Dirr, Rüdiger Daub

Chair of Production Technology and Energy Storage Systems

Research output: Contribution to journal › Article › peer-review

Abstract

The mating of electrical connectors (ECs) is predominantly carried out manually in today’s production due to small required tolerances between the plug and its socket. Automating this process offers economic incentives due to the widespread use of ECs. To achieve this, a deep learning-based 2D computer vision system is proposed for a precise localization of sockets. Herefore, a modified U-Net for keypoint prediction with heatmaps is developed and tailored for a production-like scenario. This method outperforms a commercial state-of-the-art template-based matching algorithm on five out of six EC types. In an experimental evaluation, the robot autonomously mated 75–100% of ECs successfully, depending on the EC type.

Original language	English
Journal	Production Engineering
DOIs	https://doi.org/10.1007/s11740-024-01299-7
State	Accepted/In press - 2024

Keywords

Assembly
Computer vision
Correspondence matching
Pose estimation
Reflections
Robotics

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10.1007/s11740-024-01299-7

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title = "Deep learning-based localization of electrical connector sockets for automated mating",

abstract = "The mating of electrical connectors (ECs) is predominantly carried out manually in today{\textquoteright}s production due to small required tolerances between the plug and its socket. Automating this process offers economic incentives due to the widespread use of ECs. To achieve this, a deep learning-based 2D computer vision system is proposed for a precise localization of sockets. Herefore, a modified U-Net for keypoint prediction with heatmaps is developed and tailored for a production-like scenario. This method outperforms a commercial state-of-the-art template-based matching algorithm on five out of six EC types. In an experimental evaluation, the robot autonomously mated 75–100% of ECs successfully, depending on the EC type.",

keywords = "Assembly, Computer vision, Correspondence matching, Pose estimation, Reflections, Robotics",

author = "Leopold Beck and Daniel Gebauer and Thomas Rauh and Jonas Dirr and R{\"u}diger Daub",

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T1 - Deep learning-based localization of electrical connector sockets for automated mating

AU - Beck, Leopold

AU - Gebauer, Daniel

AU - Rauh, Thomas

AU - Dirr, Jonas

AU - Daub, Rüdiger

N1 - Publisher Copyright: © The Author(s) under exclusive licence to German Academic Society for Production Engineering (WGP) 2024.

PY - 2024

Y1 - 2024

N2 - The mating of electrical connectors (ECs) is predominantly carried out manually in today’s production due to small required tolerances between the plug and its socket. Automating this process offers economic incentives due to the widespread use of ECs. To achieve this, a deep learning-based 2D computer vision system is proposed for a precise localization of sockets. Herefore, a modified U-Net for keypoint prediction with heatmaps is developed and tailored for a production-like scenario. This method outperforms a commercial state-of-the-art template-based matching algorithm on five out of six EC types. In an experimental evaluation, the robot autonomously mated 75–100% of ECs successfully, depending on the EC type.

AB - The mating of electrical connectors (ECs) is predominantly carried out manually in today’s production due to small required tolerances between the plug and its socket. Automating this process offers economic incentives due to the widespread use of ECs. To achieve this, a deep learning-based 2D computer vision system is proposed for a precise localization of sockets. Herefore, a modified U-Net for keypoint prediction with heatmaps is developed and tailored for a production-like scenario. This method outperforms a commercial state-of-the-art template-based matching algorithm on five out of six EC types. In an experimental evaluation, the robot autonomously mated 75–100% of ECs successfully, depending on the EC type.

KW - Assembly

KW - Computer vision

KW - Correspondence matching

KW - Pose estimation

KW - Reflections

KW - Robotics

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AN - SCOPUS:85197492990

SN - 0944-6524

JO - Production Engineering

JF - Production Engineering

ER -

Deep learning-based localization of electrical connector sockets for automated mating

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