Meta-learning enhanced adaptive robot control strategy for automated PCB assembly

IF 12.2 1区 工程技术 Q1 ENGINEERING, INDUSTRIAL
Jieyang Peng , Dongkun Wang , Junkai Zhao , Yunfei Teng , Andreas Kimmig , Xiaoming Tao , Jivka Ovtcharova
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引用次数: 0

Abstract

The assembly of printed circuit boards (PCBs) is one of the standard processes in chip production, directly contributing to the quality and performance of the chips. In the automated PCB assembly process, machine vision and coordinate localization methods are commonly employed to guide the positioning of assembly units. However, occlusion or poor lighting conditions can affect the effectiveness of machine vision-based methods. Additionally, the assembly of odd-form components requires highly specialized fixtures for assembly unit positioning, leading to high costs and low flexibility, especially for multi-variety and small-batch production. Drawing on these considerations, a vision-free, model-agnostic meta-method for compensating robotic position errors is proposed, which maximizes the probability of accurate robotic positioning through interactive feedback, thereby reducing the dependency on visual feedback and mitigating the impact of occlusions or lighting variations. The proposed method endows the robot with the capability to learn and adapt to various position errors, inspired by the human instinct for grasping under uncertainties. Furthermore, it is a self-adaptive method that can accelerate the robotic positioning process as more examples are incorporated and learned. Empirical studies show that the proposed method can handle a variety of odd-form components without relying on specialized fixtures, while achieving similar assembly efficiency to highly dedicated automation equipment. As of the writing of this paper, the proposed meta-method has already been implemented in a robotic-based assembly line for odd-form electronic components. Since PCB assembly involves various electronic components with different sizes, shapes, and functions, subsequent studies can focus on assembly sequence and assembly route optimization to further enhance assembly efficiency.
用于 PCB 自动装配的元学习增强型自适应机器人控制策略
印刷电路板(PCB)组装是芯片生产的标准流程之一,直接影响芯片的质量和性能。在印刷电路板自动装配过程中,通常采用机器视觉和坐标定位方法来指导装配单元的定位。然而,遮挡或照明条件差会影响基于机器视觉的方法的有效性。此外,异形元件的装配需要高度专业化的夹具进行装配单元定位,导致成本高、灵活性低,尤其是在多品种和小批量生产时。基于这些考虑,我们提出了一种无视觉、与模型无关的元方法,用于补偿机器人位置误差,通过交互式反馈最大限度地提高机器人准确定位的概率,从而降低对视觉反馈的依赖,并减轻遮挡或光照变化的影响。受人类在不确定情况下抓取的本能启发,所提出的方法赋予机器人学习和适应各种位置误差的能力。此外,它还是一种自适应方法,随着更多实例的加入和学习,可以加速机器人定位过程。实证研究表明,所提出的方法可以处理各种奇形怪状的组件,而无需依赖专门的夹具,同时还能达到与高度专用自动化设备类似的装配效率。截至本文撰写之时,所提出的元方法已在一条基于机器人的奇形电子元件装配线上得以实施。由于印刷电路板组装涉及各种不同尺寸、形状和功能的电子元件,后续研究可侧重于组装顺序和组装路径优化,以进一步提高组装效率。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Journal of Manufacturing Systems
Journal of Manufacturing Systems 工程技术-工程:工业
CiteScore
23.30
自引率
13.20%
发文量
216
审稿时长
25 days
期刊介绍: The Journal of Manufacturing Systems is dedicated to showcasing cutting-edge fundamental and applied research in manufacturing at the systems level. Encompassing products, equipment, people, information, control, and support functions, manufacturing systems play a pivotal role in the economical and competitive development, production, delivery, and total lifecycle of products, meeting market and societal needs. With a commitment to publishing archival scholarly literature, the journal strives to advance the state of the art in manufacturing systems and foster innovation in crafting efficient, robust, and sustainable manufacturing systems. The focus extends from equipment-level considerations to the broader scope of the extended enterprise. The Journal welcomes research addressing challenges across various scales, including nano, micro, and macro-scale manufacturing, and spanning diverse sectors such as aerospace, automotive, energy, and medical device manufacturing.
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