{"title":"利用机器学习驱动的优化技术提高气溶胶喷射印刷的性能","authors":"Prashantkumar Pandey, Steffen Ziesche, Gauranggiri Meghanathi","doi":"10.1002/appl.202300110","DOIUrl":null,"url":null,"abstract":"<p>Aerosol jet printing is a promising technology for printing functional materials on a variety of substrates with high precision and resolution. This technology has the potential to revolutionize the manufacturing industry by providing a low-cost, high-resolution printing technique that can be used to produce additively printed electronics, sensors, and energy devices. However, the optimization of this process has traditionally relied on time-consuming trial-and-error methods, hampering its efficiency and scalability. Machine learning (ML) models have the potential to overcome these challenges and improve the quality, speed, and efficiency of the printing process. In this paper, we propose an approach that leverages ML algorithms to streamline and enhance the aerosol jet printing optimization process. Our methodology involves data collection through systematic experimentation with various parameter settings. This data set serves as the foundation for training different ML model capable of predicting printed line characteristics and optimal printing process parameter. We validate our approach by performing experiments on different inks, and we compare the results of our ML-based optimization approach to those obtained using traditional trial-and-error methods. The results demonstrate that our approach offers significantly higher accuracy and efficiency. To enhance our approach's accessibility and ease of use, we incorporate AutoML techniques which automates the process of selecting the most suitable ML algorithms and hyperparameters, reducing the burden of manual configuration. Furthermore, we introduce a user-friendly web-based interface that facilitates the entire ML pipeline, from data preprocessing to prediction and batch processing. This interface empowers users to efficiently manage and manipulate their data, select appropriate ML algorithms, and execute predictions, ultimately improving accuracy and model performance.</p>","PeriodicalId":100109,"journal":{"name":"Applied Research","volume":"3 5","pages":""},"PeriodicalIF":0.0000,"publicationDate":"2024-04-05","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1002/appl.202300110","citationCount":"0","resultStr":"{\"title\":\"Improving performance of aerosol jet printing using machine learning-driven optimization\",\"authors\":\"Prashantkumar Pandey, Steffen Ziesche, Gauranggiri Meghanathi\",\"doi\":\"10.1002/appl.202300110\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p>Aerosol jet printing is a promising technology for printing functional materials on a variety of substrates with high precision and resolution. This technology has the potential to revolutionize the manufacturing industry by providing a low-cost, high-resolution printing technique that can be used to produce additively printed electronics, sensors, and energy devices. However, the optimization of this process has traditionally relied on time-consuming trial-and-error methods, hampering its efficiency and scalability. Machine learning (ML) models have the potential to overcome these challenges and improve the quality, speed, and efficiency of the printing process. In this paper, we propose an approach that leverages ML algorithms to streamline and enhance the aerosol jet printing optimization process. Our methodology involves data collection through systematic experimentation with various parameter settings. This data set serves as the foundation for training different ML model capable of predicting printed line characteristics and optimal printing process parameter. We validate our approach by performing experiments on different inks, and we compare the results of our ML-based optimization approach to those obtained using traditional trial-and-error methods. The results demonstrate that our approach offers significantly higher accuracy and efficiency. To enhance our approach's accessibility and ease of use, we incorporate AutoML techniques which automates the process of selecting the most suitable ML algorithms and hyperparameters, reducing the burden of manual configuration. Furthermore, we introduce a user-friendly web-based interface that facilitates the entire ML pipeline, from data preprocessing to prediction and batch processing. 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引用次数: 0
摘要
气溶胶喷射打印是一种前景广阔的技术,可在各种基底上打印高精度、高分辨率的功能材料。这项技术提供了一种低成本、高分辨率的打印技术,可用于生产加成打印电子器件、传感器和能源设备,从而有可能彻底改变制造业。然而,该工艺的优化历来依赖于耗时的试错方法,从而影响了其效率和可扩展性。机器学习(ML)模型有可能克服这些挑战,提高打印过程的质量、速度和效率。在本文中,我们提出了一种利用机器学习(ML)算法来简化和增强气溶胶喷射打印优化流程的方法。我们的方法包括通过对各种参数设置进行系统实验来收集数据。该数据集是训练不同 ML 模型的基础,这些模型能够预测印刷线特性和最佳印刷工艺参数。我们通过在不同油墨上进行实验来验证我们的方法,并将我们基于 ML 的优化方法的结果与使用传统试错方法获得的结果进行比较。结果表明,我们的方法具有更高的准确性和效率。为了提高方法的可访问性和易用性,我们采用了 AutoML 技术,该技术可自动选择最合适的 ML 算法和超参数,减轻了手动配置的负担。此外,我们还引入了基于网络的用户友好界面,为从数据预处理到预测和批量处理的整个 ML 管道提供便利。该界面使用户能够高效地管理和操作数据、选择合适的 ML 算法并执行预测,最终提高准确性和模型性能。本文受版权保护,保留所有权利。
Improving performance of aerosol jet printing using machine learning-driven optimization
Aerosol jet printing is a promising technology for printing functional materials on a variety of substrates with high precision and resolution. This technology has the potential to revolutionize the manufacturing industry by providing a low-cost, high-resolution printing technique that can be used to produce additively printed electronics, sensors, and energy devices. However, the optimization of this process has traditionally relied on time-consuming trial-and-error methods, hampering its efficiency and scalability. Machine learning (ML) models have the potential to overcome these challenges and improve the quality, speed, and efficiency of the printing process. In this paper, we propose an approach that leverages ML algorithms to streamline and enhance the aerosol jet printing optimization process. Our methodology involves data collection through systematic experimentation with various parameter settings. This data set serves as the foundation for training different ML model capable of predicting printed line characteristics and optimal printing process parameter. We validate our approach by performing experiments on different inks, and we compare the results of our ML-based optimization approach to those obtained using traditional trial-and-error methods. The results demonstrate that our approach offers significantly higher accuracy and efficiency. To enhance our approach's accessibility and ease of use, we incorporate AutoML techniques which automates the process of selecting the most suitable ML algorithms and hyperparameters, reducing the burden of manual configuration. Furthermore, we introduce a user-friendly web-based interface that facilitates the entire ML pipeline, from data preprocessing to prediction and batch processing. This interface empowers users to efficiently manage and manipulate their data, select appropriate ML algorithms, and execute predictions, ultimately improving accuracy and model performance.