Integrating III-V, Si, and polymer waveguides for optical interconnects: RAPIDO

SPIE OPTO Pub Date : 2016-05-24 DOI:10.1117/12.2214786

T. Aalto, M. Harjanne, B. Offrein, C. Caër, C. Neumeyr, A. Malacarne, M. Guina, R. Sheehan, F. Peters, P. Melanen

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引用次数: 4

Abstract

We present a vision for the hybrid integration of advanced transceivers at 1.3 μm wavelength, and the progress done towards this vision in the EU-funded RAPIDO project. The final goal of the project is to make five demonstrators that show the feasibility of the proposed concepts to make optical interconnects and packet-switched optical networks that are scalable to Pb/s systems in data centers and high performance computing. Simplest transceivers are to be made by combining directly modulated InP VCSELs with 12 μm SOI multiplexers to launch, for example, 200 Gbps data into a single polymer waveguide with 4 channels to connect processors on a single line card. For more advanced transceivers we develop novel dilute nitride amplifiers and modulators that are expected to be more power-efficient and temperatureinsensitive than InP devices. These edge-emitting III-V chips are flip-chip bonded on 3 μm SOI chips that also have polarization and temperature independent multiplexers and low-loss coupling to the 12 μm SOI interposers, enabling to launch up to 640 Gbps data into a standard single mode (SM) fiber. In this paper we present a number of experimental results, including low-loss multiplexers on SOI, zero-birefringence Si waveguides, micron-scale mirrors and bends with 0.1 dB loss, direct modulation of VCSELs up to 40 Gbps, ±0.25μm length control for dilute nitride SOA, strong band edge shifts in dilute nitride EAMs and SM polymer waveguides with 0.4 dB/cm loss.

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集成III-V, Si和聚合物波导的光互连:RAPIDO

我们提出了1.3 μm波长先进收发器混合集成的愿景，以及在欧盟资助的RAPIDO项目中实现这一愿景的进展。该项目的最终目标是制作5个演示，展示所提出概念的可行性，以制作可扩展到数据中心Pb/s系统和高性能计算的光互连和分组交换光网络。最简单的收发器是通过将直接调制的InP vcsel与12 μm SOI多路复用器相结合来制造的，例如，将200 Gbps的数据发射到具有4个通道的单个聚合物波导中，以连接单个线卡上的处理器。对于更先进的收发器，我们开发了新型稀氮化放大器和调制器，预计比InP器件更节能和温度敏感。这些边缘发射III-V芯片倒装在3 μm SOI芯片上，该芯片还具有极化和温度无关的多路复用器，并与12 μm SOI中间层具有低损耗耦合，能够将高达640 Gbps的数据发射到标准单模(SM)光纤中。在本文中，我们展示了一系列实验结果，包括SOI上的低损耗多路复用器、零双折射Si波导、0.1 dB损耗的微米尺度反射和弯曲、高达40 Gbps的vcsel直接调制、稀氮SOA的±0.25μm长度控制、稀氮eam的强带边偏移和0.4 dB/cm损耗的SM聚合物波导。

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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SPIE OPTO

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