Balancing optical system design and optical fabrication chain design

O. Faehnle, E. Langenbach, I. Livshits
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Abstract

The design of optical systems has two main tasks: (a) their optimal optical performance and (b) their optimal producibility; whereby the latter has to comply with the "magic triangle" of optical performance quality, fabrication cost and manufacturing throughput. Unfortunately, for decades there has been a major mismatch in designing optical systems. On one hand, optical system designers are well supported by State-of-The-Art optical design software tools while on the other hand, the design of optical fabrication chains and their cost, which is strongly interlinked with the parameters and tolerances of the optical system design, is still today completely depending on humans experiences and knowledge. Consequently, while optical system designs are well optimized for optical system performance, their optimization for optimal producibility and manufacturing chain design is not possible during the design phase of the optical system itself. This paper reports on the application of a novel approach to optical design strategies. Within a Swiss research project called PanDao, a new type of software tool was developed enabling the integration of producibility analyses and fabrication chain optimizations into the optical design process. PanDao reads in lens parameters and tolerances as described in the ISO 10110 standards and generates the optimal fabrication chain at minimum cost, taking more than 300 optical fabrication techniques into account.
平衡光学系统设计和光学制造链设计
光学系统的设计有两个主要任务:(a)其最佳光学性能和(b)其最佳生产效率;后者必须符合光学性能质量、制造成本和制造吞吐量的“魔三角”。不幸的是,几十年来,在设计光学系统时存在一个主要的不匹配。一方面,光学系统设计人员得到了最先进的光学设计软件工具的良好支持,另一方面,光学制造链的设计及其成本与光学系统设计的参数和公差密切相关,今天仍然完全取决于人类的经验和知识。因此,虽然光学系统设计在光学系统性能上得到了很好的优化,但在光学系统本身的设计阶段,它们对最佳可生产性和制造链设计的优化是不可能的。本文报道了一种新方法在光学设计策略中的应用。在一个名为PanDao的瑞士研究项目中,开发了一种新型软件工具,可以将可生产性分析和制造链优化集成到光学设计过程中。PanDao根据ISO 10110标准读取透镜参数和公差,并考虑300多种光学制造技术,以最低成本生成最佳制造链。
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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