Modulation linearity analysis of depletion-type Si ring modulator (Conference Presentation)

Silicon Photonics XIV Pub Date : 2019-03-04 DOI:10.1117/12.2509215

Youngkwan Jo, B. Yu, S. Lischke, C. Mai, L. Zimmermann, W. Choi

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Abstract

The depletion-type Si ring modulator (RM) is of great interest among many Si photonic devices for optical interconnect applications because it has a small size, low power consumption, and large modulation bandwidth. Although the major application of the Si RM are digital optical interconnect systems, there is another application of importance, namely microwave photonics in which the modulation linearity is a key performance parameter. We investigate the modulation linearity performance in terms of spurious-free dynamic range (SFDR) of a RM device fabricated by IHP Si PIC foundry. The device has 8-um radius, 290-nm coupling gap and the nominal peak doping concentration of 7×1017 cm−3 for p-region and 3×1018 cm−3 for n-region. The measured SFDR is 78.7 dB·Hz2/3. The major sources of non-linearity of this device are the nonlinear free-carrier plasma dispersion effect in PN junction as well as the nonlinear resonance characteristics. We also perform the numerical simulation of RM SFDR using key device parameters extracted from measurement. The simulation results match well with the measurement results. With this numerical model, we are able to identify the exact cause of RM nonlinearity and come up with suggestions for improving RM linearity.

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耗尽型硅环调制器的调制线性度分析(会议报告)

耗尽型硅环调制器(RM)具有体积小、功耗低、调制带宽大等优点，是许多用于光互连应用的硅光子器件中备受关注的器件。虽然Si RM的主要应用是数字光学互连系统，但还有另一个重要的应用，即微波光子学，其中调制线性度是一个关键的性能参数。我们从无杂散动态范围(SFDR)的角度研究了IHP硅PIC代工厂制造的RM器件的调制线性性能。该器件半径为8um，耦合间隙为290nm, p区和n区名义掺杂峰浓度分别为7×1017 cm−3和3×1018 cm−3。测量到的SFDR为78.7 dB·Hz2/3。该器件非线性的主要来源是PN结的非线性自由载流子等离子体色散效应和非线性共振特性。我们还使用从测量中提取的关键器件参数对RM SFDR进行了数值模拟。仿真结果与实测结果吻合较好。利用该数值模型，我们能够准确地识别出RM非线性的原因，并提出改善RM线性度的建议。

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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Silicon Photonics XIV

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