Surface normal photonic crystal waveguide coupling for N/sup 3/ distributed optoelectronic crossbar

Digest of the LEOS Summer Topical Meetings Biophotonics/Optical Interconnects and VLSI Photonics/WBM Microcavities, 2004. Pub Date : 2004-06-28 DOI:10.1109/LEOSST.2004.1338696

P. Guilfoyle, D. Louderback, G. Pickrell, G. Witzens, A. Scherer

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Abstract

The realization of the N/sup 3/ distributed optoelectronic crossbar requires the incorporation of bidirectional transceiver modules. The current design philosophy of these modules in their single wavelength configuration consist of the integration of VCSEL and RCE detection devices monolithically integrated with a bidirectional common waveguide. Coupling into this common waveguide is currently under investigation utilizing two methods 1.) surface normal coupling using a buried grating coupler external but monolithic surface normal coupling utilizing photonic crystal. This paper will briefly discuss the first method and its drawbacks which motivate the second photonic crystal implementation method. Our initial design work has been accomplished at 980 nm. The measure reflectance spectrum of the VCSEL/PD epitaxy structure prior to the fabrication of the photonic crystal coupler and waveguide layer.

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N/sup /分布式光电交叉杆的表面法向光子晶体波导耦合

N/sup /分布式光电交叉棒的实现需要结合双向收发模块。目前，这些模块的单波长配置的设计理念是将VCSEL和RCE检测设备与双向共波导单片集成在一起。目前正在研究利用两种方法耦合到这种共波导中:1)表面法向耦合，使用埋地光栅耦合器，外部使用单片表面法向耦合，利用光子晶体。本文将简要讨论激发第二种光子晶体实现方法的第一种方法及其缺陷。我们的初步设计工作已经在980纳米完成。在制作光子晶体耦合器和波导层之前，测量了VCSEL/PD外延结构的反射光谱。

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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Digest of the LEOS Summer Topical Meetings Biophotonics/Optical Interconnects and VLSI Photonics/WBM Microcavities, 2004.

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