Guided-mode Resonance Filter for Micro-optic Spectrometer

2020 IEEE 70th Electronic Components and Technology Conference (ECTC) Pub Date : 2020-06-01 DOI:10.1109/ectc32862.2020.00283

J. Inoue, S. Ura, K. Kintaka

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引用次数: 1

Abstract

Spectrometers are usually composed of diffraction gratings and prisms, and become large in size for high wavelength resolution. High-density integration of narrowband-pass filters of different wavelengths on a substrate can be expected to produce an ultra-compact spectrometer. We focused on guided-mode resonance (GMR) filters as such filters. The GMR filter consists of a thin-film waveguide and a sub-wavelength grating. GMR filters of different filtering wavelengths can be integrated in the same substrate because their periodic structure in refractive index spread along in-plane direction. On the other hand, GMR filter normally needs an aperture size and beam diameter of hundreds of microns and is not suitable for high-density integration. In this study, we proposed and investigated a GMR filter of a single-layer cross grating for a compact narrowband-pass filter. Different guided modes contributing to the broadband and narrowband reflection propagate orthogonally each other. By using simultaneously these guided modes, both reflections are cancelled at the competing wavelengths, resulting in high transmittance. In this paper, design examples with numerical simulation results are presented. It was predicted that a passband of 15 nm was obtained in the stopband of 200 nm for an incident beam of a 10-micron diameter.

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用于微光学光谱仪的导模共振滤波器

光谱仪通常由衍射光栅和棱镜组成，为了获得高波长分辨率，光谱仪的尺寸变得更大。在衬底上高密度集成不同波长的窄带通滤波器有望制造出超紧凑光谱仪。我们重点研究了导模谐振(GMR)滤波器。GMR滤波器由薄膜波导和亚波长光栅组成。不同滤波波长的GMR滤波器由于其折射率的周期性结构沿平面扩散，可以集成在同一衬底中。另一方面，GMR滤波器通常需要孔径大小和光束直径数百微米，不适合高密度集成。在这项研究中，我们提出并研究了一种用于紧凑型窄带通滤波器的单层交叉光栅GMR滤波器。不同的引导模式有助于宽带和窄带反射相互正交传播。通过同时使用这些引导模式，两种反射在竞争波长处被抵消，从而产生高透射率。文中给出了设计实例和数值模拟结果。结果表明，对于直径为10微米的入射光束，在200 nm的阻带中可得到15 nm的通带。

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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2020 IEEE 70th Electronic Components and Technology Conference (ECTC)

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