Abstract
This paper addresses a critical challenge in Printed Circuit Board (PCB) manufacturing by proposing an AI-driven, fully automated drilling machine that employs sophisticated path-planning techniques. Current methodologies often fail to adequately assess designs with varying hole sizes, diverse component placements, and complex geometries, leading to compromised precision and increased manufacturing times. Our innovative approach leverages advanced algorithms to intelligently analyze PCB designs and optimize drilling paths, significantly reducing production time and minimizing errors. By automating the drilling process, we enhance overall productivity while ensuring precise hole placement, essential for maintaining high-quality circuit boards. Utilizing KiCAD EDA software, we automate the generation of Gerber files and G-Codes, demonstrating a remarkable 13-fold improvement in routing efficiency compared to manual methods. Our case studies validate the effectiveness of this system, showcasing successful continuity tests and superior quality finishes in PCB production. This research contributes to the advancement of PCB manufacturing. It lays the groundwork for future explorations into machine learning algorithms and optimization techniques, further enhancing the efficiency and applicability of AI in electronics design.