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Main Authors: Kim, Yunho, Nguyen, Quan, Kim, Taewhan, Heo, Youngjin, Lee, Joonho
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2604.22235
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author Kim, Yunho
Nguyen, Quan
Kim, Taewhan
Heo, Youngjin
Lee, Joonho
author_facet Kim, Yunho
Nguyen, Quan
Kim, Taewhan
Heo, Youngjin
Lee, Joonho
contents Industrial robots are widely used in manufacturing, yet most manipulation still depends on fixed waypoint scripts that are brittle to environmental changes. Learning-based control offers a more adaptive alternative, but it remains unclear whether such methods, still mostly confined to laboratory demonstrations, can sustain hours of reliable operation, deliver consistent quality, and behave safely around people on a live production line. Here we present Learning-Augmented Robotic Automation, a hybrid system that integrates learned task controllers and a neural 3D safety monitor into conventional industrial workflows. We deployed the system on an electric-motor production line to automate deformable cable insertion and soldering under real manufacturing constraints, a step previously performed manually by human workers. With less than 20 min of real-world data per task, the system operated continuously for 5 h 10 min, producing 108 motors without physical fencing and achieving a 99.4% pass rate on product-level quality-control tests. It maintained near-human takt time while reducing variability in solder-joint quality and cycle time. These results establish a practical pathway for extending industrial automation with learning-based methods.
format Preprint
id arxiv_https___arxiv_org_abs_2604_22235
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Learning-augmented robotic automation for real-world manufacturing
Kim, Yunho
Nguyen, Quan
Kim, Taewhan
Heo, Youngjin
Lee, Joonho
Robotics
Artificial Intelligence
Machine Learning
Industrial robots are widely used in manufacturing, yet most manipulation still depends on fixed waypoint scripts that are brittle to environmental changes. Learning-based control offers a more adaptive alternative, but it remains unclear whether such methods, still mostly confined to laboratory demonstrations, can sustain hours of reliable operation, deliver consistent quality, and behave safely around people on a live production line. Here we present Learning-Augmented Robotic Automation, a hybrid system that integrates learned task controllers and a neural 3D safety monitor into conventional industrial workflows. We deployed the system on an electric-motor production line to automate deformable cable insertion and soldering under real manufacturing constraints, a step previously performed manually by human workers. With less than 20 min of real-world data per task, the system operated continuously for 5 h 10 min, producing 108 motors without physical fencing and achieving a 99.4% pass rate on product-level quality-control tests. It maintained near-human takt time while reducing variability in solder-joint quality and cycle time. These results establish a practical pathway for extending industrial automation with learning-based methods.
title Learning-augmented robotic automation for real-world manufacturing
topic Robotics
Artificial Intelligence
Machine Learning
url https://arxiv.org/abs/2604.22235