A New Two-Sided Coupling Channel Drop Filter Based on a Two-Dimensional Photonic Crystal

Xiang Nan Zhang; Gui Qiang Liu; Ying Hu; Zheng Jie Cai; Yuan Hao Chen

doi:10.4028/www.scientific.net/AMR.760-762.417

Paper Titles

The Design of Wideband Microstrip Bandpass Filter Using Dual Stepped Impedance Stub-Loaded Resonator
p.401

Fabrication of 3D Photonic Crystals of Non-Magnetic Ellipsoids with Different Aspect Ratio
p.405

The Application of Non-Destructive Testing Based on Terahertz Technology in the Field of Smart Grid
p.409

Multiple Healing Fatigue Damage by Laser Shock Peening for Copper Thin Film
p.413

A New Two-Sided Coupling Channel Drop Filter Based on a Two-Dimensional Photonic Crystal
p.417

Mechanism of Plasma Radiation Optics-Ammunition Inspired by Electrically Exploding Wires
p.421

Electronic Structure and Optical Properties of InN: A First-Principles Study
p.425

Equivalent Luminous Efficiency - A Normalization Index to Luminous Efficiency of Luminaries
p.429

A Novel Integrated MEMS Pyramidal Horn Antenna for Terahertz Applications
p.434

HomeAdvanced Materials ResearchAdvanced Materials Research Vols. 760-762A New Two-Sided Coupling Channel Drop Filter Based...

A New Two-Sided Coupling Channel Drop Filter Based on a Two-Dimensional Photonic Crystal

Abstract:

We design a new two-sided coupling channel drop filter (CDF) based on a two-dimensional (2D) photonic crystal (PC). Three channels formed by line defects for light propagation, two L4 resonators positioned at both sides of the input waveguide for light coupling, and one point defect micro-cavity in the bus waveguide for wavelength-selective reflection are introduced into the PC structure. The optical characteristics of this proposed structure are calculated by finite-difference time-domain (FDTD) method combined with the perfectly matched layers (PMLs) as the boundary conditions. Three wavelengths centered at 1550, 1575 and 1610 nm within the limit of communication windows are successfully separated in three channels by adjusting the size of coupling rods and the positions of L4 resonators and micro-cavity. High transmission efficiency and more than 20 nm channel spacing are achieved. These demonstrate that our proposed structure is suitable for photonic integrated circuits (PICs) and coarse wavelength division multiplexing (WDM) optical communication systems.