On-chip Spectrometer Formed by a Multi-stage Structure

Semiconductor Science and Information Devices Pub Date : 2019-10-31 DOI:10.30564/ssid.v1i1.648

Li Jin, Shaoyu Zhao, Zhipeng Hu, Xiaoyan Hu

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Abstract

With apparent size and weight advantages, on-chip spectrometer could be a good choice for the spectrum analysis application which has been widely used in numerous areas such as optical network performance monitoring, materials analysis and medical research. In order to realize the broadband and the high resolution simultaneously, we propose a new on-chip spectrometer structure, which is a two-stage structure. The coarse wavelength division is realized by the cascaded Mach-Zehnder interferometers, which is the first stage of the spectrometer. The output of the Mach-Zehnder interferometers are further dispersed by the second stage structure, which can be realized either by arrayed waveguide gratings or by digital Fourier transform spectrometer structure. We further implemented the thermo-optic modulation for the arrayed waveguide gratings to achieve a higher spectral resolution. The output channel wavelengths of the spectrometer are modulated by the embedded heater to obtain the first order derivative spectra of the input optical signal to obtain a 2nm resolution. With respect to the computer simulation and device characterization results, the 400nm spectral range and the nanoscale resolution have been demonstrated.

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由多级结构组成的片上光谱仪

片上光谱仪具有明显的尺寸和重量优势，是光谱分析应用的良好选择，已广泛应用于光网络性能监测、材料分析和医学研究等众多领域。为了同时实现宽带和高分辨率，我们提出了一种新的片上谱仪结构，即两级结构。粗分波长是由级联的马赫-曾德尔干涉仪实现的，这是光谱仪的第一步。第二级结构进一步分散了马赫-曾德尔干涉仪的输出，这可以通过阵列波导光栅或数字傅立叶变换光谱仪结构来实现。我们进一步实现了阵列波导光栅的热光调制，以获得更高的光谱分辨率。通过嵌入式加热器对光谱仪的输出通道波长进行调制，得到输入光信号的一阶导数光谱，得到2nm分辨率。根据计算机模拟和器件表征结果，证明了400nm的光谱范围和纳米级分辨率。

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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Semiconductor Science and Information Devices

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