一种层状悬臂波导光开关

J. Tsai, A. Zhang, G. Li, M. Bachman
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引用次数: 2

摘要

本文介绍了利用无源二维光学元件和有源光学元件的光学层压板光学的使用。这在概念验证1×2光开关概念中得到了证明,该概念与层压板制造的微机电系统(MEMS)兼容。该装置采用精密切割形成悬臂结构的波导结构。悬臂作为一个可弯曲的波导,可以定位到两个位置,与两个相应的波导中的一个对齐。光束被引导到悬臂梁的前端,该悬臂梁将信号耦合到悬臂梁的尖端。悬臂尖端可以定位为与两个第二波导中的一个对齐,从而将光信号发送到指定的输出端。悬臂使用电磁致动力移动,并且可以磁锁定在位置上,因此不需要进一步的动力来保持它。这项工作的独特之处在于,整个设备可以使用封装和精密PCB代工厂中常见的层压板技术制造。这使得人们可以利用硅加工所不具备的材料和制造方法,例如使用柔性聚合物悬臂波导和磁性材料。此外,它还可以集成到印刷电路中。我们已经展示了这个设备的概念验证。本文介绍了层压板结构的设计,并给出了初步结果。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A laminate cantilever waveguide optical switch
This paper describes the use of optical laminate optics that utilizes both passive 2-D optical elements and active components. This is demonstrated in a proof-of-concept 1×2 optical switch concept that is compatible with micro electrical mechanical systems (MEMS) fabricated in laminates. The device uses a waveguide structure that is precision cut to form a cantilever structure. The cantilever, which acts as a bendable waveguide, can be positioned into two locations to align with one of two corresponding waveguides. A light beam is directed into the front end of the cantilever which couples the signal to the tip of the cantilever. The cantilever tip can be positioned to align with one of two second waveguides, thereby sending the optical signal into a specified output. The cantilever is moved using an electromagnetic actuation force, and can be magnetically latched in position so that no further power is required to hold it in place. The unique aspect of this work is that the entire device can be fabricated using laminate technology commonly found in packaging and precision PCB foundries. This allows one to utilize materials and manufacturing methods not available to silicon processing, such as the use of a flexible polymer cantilever waveguide and magnetic materials. Further, it allows integration into printed circuits. We have demonstrated proof-of-concept for this device. This paper describes the design of the structure in laminates and shows initial results.
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