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Main Authors: Correas-Naranjo, Luis, Camacho-Sánchez, Miguel, Launet, Laëtitia, Zuric, Milena, Naranjo, Valery
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2512.02026
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author Correas-Naranjo, Luis
Camacho-Sánchez, Miguel
Launet, Laëtitia
Zuric, Milena
Naranjo, Valery
author_facet Correas-Naranjo, Luis
Camacho-Sánchez, Miguel
Launet, Laëtitia
Zuric, Milena
Naranjo, Valery
contents In the pursuit of sustainable manufacturing, ultra-short pulse laser micromachining stands out as a promising solution while also offering high-precision and qualitative laser processing. However, unlocking the full potential of ultra-short pulse lasers requires an optimized monitoring system capable of early detection of defective workpieces, regardless of the preprocessing technique employed. While advances in machine learning can help predict process quality features, the complexity of monitoring data necessitates reducing both model size and data dimensionality to enable real-time analysis. To address these challenges, this paper introduces a machine learning framework designed to enhance surface quality assessment across diverse preprocessing techniques. To facilitate real-time laser processing monitoring, our solution aims to optimize the computational requirements of the machine learning model. Experimental results show that the proposed model not only outperforms the generalizability achieved by previous works across diverse preprocessing techniques but also significantly reduces the computational requirements for training. Through these advancements, we aim to establish the baseline for a more sustainable manufacturing process.
format Preprint
id arxiv_https___arxiv_org_abs_2512_02026
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Towards Sustainable Precision: Machine Learning for Laser Micromachining Optimization
Correas-Naranjo, Luis
Camacho-Sánchez, Miguel
Launet, Laëtitia
Zuric, Milena
Naranjo, Valery
Signal Processing
Artificial Intelligence
In the pursuit of sustainable manufacturing, ultra-short pulse laser micromachining stands out as a promising solution while also offering high-precision and qualitative laser processing. However, unlocking the full potential of ultra-short pulse lasers requires an optimized monitoring system capable of early detection of defective workpieces, regardless of the preprocessing technique employed. While advances in machine learning can help predict process quality features, the complexity of monitoring data necessitates reducing both model size and data dimensionality to enable real-time analysis. To address these challenges, this paper introduces a machine learning framework designed to enhance surface quality assessment across diverse preprocessing techniques. To facilitate real-time laser processing monitoring, our solution aims to optimize the computational requirements of the machine learning model. Experimental results show that the proposed model not only outperforms the generalizability achieved by previous works across diverse preprocessing techniques but also significantly reduces the computational requirements for training. Through these advancements, we aim to establish the baseline for a more sustainable manufacturing process.
title Towards Sustainable Precision: Machine Learning for Laser Micromachining Optimization
topic Signal Processing
Artificial Intelligence
url https://arxiv.org/abs/2512.02026