Two Frequency-Division Demultiplexing Using Photonic Waveguides by the Presence of Two Geometric Defects

El-Aouni Mimoun, Ben-Ali Youssef, El Kadmiri Ilyass, Ouariach Abdelaziz, Bria Driss
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Abstract

This paper presents a theoretical work of a new device concept for frequency division demultiplexing with excellent performance based on waveguides system containing segments and loops in the presence of two geometrics defects. This system permits the separation of two frequency, based on 1D photonic waveguides loops structures. The system under consideration possesses a Y‑shaped demultiplexer configuration, consisting of a single input and two output channels (transmission lines). Each output channel contains an alternating unit cell consisting of a segment and a loop. The creation of a geometrical defect at the segment level in the middle of each output line allows the creation of two defect modes inside the bandgaps. The numerical results show that this demultiplexer system is able to separate two signals (electromagnetic waves) of different frequencies and guide each signal through an output channel. We perform the analytical calculation of the transmission rates T1, T2, and reflection R using the interface response theory, which is based on Green’s function method for the proposed demultiplexer system. The proposed device offers high transmission efficiency, high quality factor and a large frequency difference between defect modes, hence, it is highly desirable for frequency division demultiplexing applications.

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利用存在两个几何缺陷的光子波导进行两次频分复用
本文介绍了一种用于频分解复用的新设备概念的理论研究,该设备性能卓越,基于波导系统,包含两个几何缺陷的波段和环路。该系统基于一维光子波导环路结构,可实现双频分离。该系统采用 Y 型解复用器配置,由一个输入通道和两个输出通道(传输线)组成。每个输出通道都包含一个交替的单元格,单元格由段和环组成。在每条输出线中间的分段处产生一个几何缺陷,从而在带隙内产生两种缺陷模式。数值结果表明,这种解复用器系统能够分离两个不同频率的信号(电磁波),并引导每个信号通过一个输出通道。我们利用基于格林函数法的界面响应理论,对所提出的解复用器系统的传输速率 T1、T2 和反射率 R 进行了分析计算。所提出的器件具有传输效率高、品质因数高和缺陷模式之间频率差大的特点,因此非常适合频分解复用应用。
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来源期刊
CiteScore
1.50
自引率
11.10%
发文量
25
期刊介绍: The journal covers a wide range of issues in information optics such as optical memory, mechanisms for optical data recording and processing, photosensitive materials, optical, optoelectronic and holographic nanostructures, and many other related topics. Papers on memory systems using holographic and biological structures and concepts of brain operation are also included. The journal pays particular attention to research in the field of neural net systems that may lead to a new generation of computional technologies by endowing them with intelligence.
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