Simple numerical scheme for modelling of nonlinear pulse propagation in coupled microring resonators Anna Sterkhova, Jiří Petráček, Jaroslav Luksch ICTON.

Slides:

Advertisements

Similar presentations

Courant and all that Consistency, Convergence Stability Numerical Dispersion Computational grids and numerical anisotropy The goal of this lecture is to.

Advertisements

Finite Difference Discretization of Hyperbolic Equations: Linear Problems Lectures 8, 9 and 10.

Application of the Root-Locus Method to the Design and Sensitivity Analysis of Closed-Loop Thermoacoustic Engines C Mark Johnson.

4 th order Embedded Boundary FDTD algorithm for Maxwell Equations Lingling Wu, Stony Brook University Roman Samulyak, BNL Tianshi Lu, BNL Application collaborators:

ASME-PVP Conference - July

All-Optical Gyroscope Based on Sagnac Effect in Photonic Crystal Coupled Cavity Waveguides and Slow Light Structures Work published in: B.Z. Steinberg,

Modelling techniques and applications Qing Tan EPFL-STI-IMT-OPTLab

1 Fields and Signals in Coupled Coaxial and Cylindrical Cavities John C. Young Chalmers M. Butler Clemson University.

EMLAB 1 Numerical Boundary Conditions. EMLAB 2 A Problem at the Boundary of the Grid We must implement the update equations for every point in the grid.

Coupled resonator slow-wave optical structures Parma, 5/6/2007 Jiří Petráček, Jaroslav Čáp

Session: Computational Wave Propagation: Basic Theory Igel H., Fichtner A., Käser M., Virieux J., Seriani G., Capdeville Y., Moczo P.  The finite-difference.

Meshless Elasticity Model and Contact Mechanics-based Verification Technique Rifat Aras 1 Yuzhong Shen 1 Michel Audette 1 Stephane Bordas 2 1 Department.

Ultrasonic Nonlinear Imaging- Tissue Harmonic Imaging.

An Optimal Nearly-Analytic Discrete Method for 2D Acoustic and Elastic Wave Equations Dinghui Yang Depart. of Math., Tsinghua University Joint with Dr.

AE/ME 339 Computational Fluid Dynamics (CFD) K. M. Isaac Professor of Aerospace Engineering.

Sharp resonance of multimode periodic waveguide open resonator defined in SOI Ph.D student: Nikolay Piskunov Supervisor: Henri Benisty Institut d’Optique.

BEM Final reportPP.1 Wave-induced oscillations in harbors of arbitrary Reporter: Chine-Feng Wu Advisor: Jeng-Tzong Chen Date: Jan. 07, 2010 Jiin-Jen Lee.

Lecture 34 - Ordinary Differential Equations - BVP CVEN 302 November 28, 2001.

The Islamic University of Gaza Faculty of Engineering Numerical Analysis ECIV 3306 Introduction.

A phase field model for binary fluid-surfactant system

Finite Difference Time Domain Method (FDTD)

P. Ackerer, IMFS, Barcelona About Discontinuous Galerkin Finite Elements P. Ackerer, A. Younès Institut de Mécanique des Fluides et des Solides,

Finite Differences Finite Difference Approximations  Simple geophysical partial differential equations  Finite differences - definitions  Finite-difference.

Hyperbolic PDEs Numerical Methods for PDEs Spring 2007 Jim E. Jones.

Interaction of radiation with atoms and ions (I) Absorption- Stimulated emission E1E1 E2E2 W 12 =W 21 Spontaneous emission More definitionsCross section.

1 EEE 431 Computational Methods in Electrodynamics Lecture 9 By Dr. Rasime Uyguroglu

IMEX Methods for Advection-Diffusion-Reaction Equations Eindhoven 2008 Speaker : Volha Shchetnikava Adviser: dr.ir.J.H.M. ten Thije Boonkkamp.

Simulation of Nonlinear Effects in Optical Fibres

HOT PLATE CONDUCTION NUMERICAL SOLVER AND VISUALIZER Kurt Hinkle and Ivan Yorgason.

Overview of Propagating Interfaces Donald Tanguay October 30, 2002.

Enhancing One‐Dimensional FDTD

Convective Heat Transfer in Porous Media filled with Compressible Fluid subjected to Magnetic Field Watit Pakdee* and Bawonsak Yuwaganit Center R & D on.

A RANS Based Prediction Method of Ship Roll Damping Moment Kumar Bappaditya Salui Supervisors of study: Professor Dracos Vassalos and Dr. Vladimir Shigunov.

WORKSHOP ON LONG-WAVE RUNUP MODELS Khairil Irfan Sitanggang and Patrick Lynett Dept of Civil & Ocean Engineering, Texas A&M University.

Akram Bitar and Larry Manevitz Department of Computer Science

1 Modeling of Nonlinear Active Circuits Using FDTD Approach Iman Farghadan & Ahmad Fayaz Department of Electrical Engineering K.N.Toosi.

A Domain Decomposition Method for Pseudo-Spectral Electromagnetic Simulations of Plasmas Jean-Luc Vay, Lawrence Berkeley Nat. Lab. Irving Haber & Brendan.

Hong-Ki Jo 1), Man-Gi Ko 2) and * In-Won Lee 3) 1) Graduate Student, Dept. of Civil Engineering, KAIST 2) Professor, Dept. of Civil Engineering, Kongju.

Graduate Institute of Astrophysics, National Taiwan University Leung Center for Cosmology and Particle Astrophysics Chia-Yu Hu OSU Radio Simulation Workshop.

Application of Bezier splines and sensitivity analysis in inverse geometry and boundary problems Iwona NOWAK*, Andrzej J. NOWAK** * Institute of Mathematics,

MECH4450 Introduction to Finite Element Methods Chapter 9 Advanced Topics II - Nonlinear Problems Error and Convergence.

1 EEE 431 Computational Methods in Electrodynamics Lecture 8 By Dr. Rasime Uyguroglu

Computational Nanophotonics Stephen K. Gray Chemistry Division Argonne National Laboratory Argonne, IL Tel:

Requirements of High Accuracy Computing 1) Adopted numerical scheme must resolve all physical time and length scales. 2) Numerical scheme must be neutrally.

1 Challenge the future Steel ball dropped into very fine sand (YouTube)

1 EEE 431 Computational Methods in Electrodynamics Lecture 7 By Dr. Rasime Uyguroglu

EE 372: Engineering Electromagnetics II Spring 2016.

Continuous wavelet transform of function f(t) at time relative to wavelet kernel at frequency scale f: "Multiscale reconstruction of shallow marine sediments.

J. Diaz, D. Kolukhin, V. Lisitsa, V. Tcheverda Coupling of the Discontinuous Galerkin and Finite Difference techniques to simulate seismic waves in the.

In this work, we propose a novel local mesh refinement algorithm based on the use of transformation optics. The new algorithm is an alternative way to.

1 EEE 431 Computational Methods in Electrodynamics Lecture 13 By Dr. Rasime Uyguroglu

Introduction to Numerical Methods I

Convection-Dominated Problems

FDTD 1D-MAP Plane Wave TFSF Simulation for Lossy and Stratified Media

FDTD Modeling of FID Signal in Chirped-Pulse Millimeter Wave Spectroscopy Alexander Heifetz1, Sasan Bakhtiari1, Hual-Teh Chien1, Stephen Gray1, Kirill.

Numerical Simulation of N-S equations in Cylindrical Coordinate

THE METHOD OF LINES ANALYSIS OF ASYMMETRIC OPTICAL WAVEGUIDES Ary Syahriar.

NUMERICAL INVESTIGATIONS OF FINITE DIFFERENCE SCHEMES

Numerical Solutions of Partial Differential Equations

Objective Numerical methods Finite volume.

Slow light in Photonic Crystals

Lossy Transmission Lines

Finite difference time domain

Investigators Tony Johnson, T. V. Hromadka II and Steve Horton

Numerical Simulation of East China Sea Tsunami by Boussinesq Equation

Diyu Yang Mentor: Xu Chen Advisor: José E. Schutt-Ainé Abstract

Wei Choon Tay and Eng Leong Tan

Modeling Debye Dispersive Media Using Efficient ADI-FDTD Method

Atilla Ozgur Cakmak, PhD

Akram Bitar and Larry Manevitz Department of Computer Science

Presentation transcript:

Simple numerical scheme for modelling of nonlinear pulse propagation in coupled microring resonators Anna Sterkhova, Jiří Petráček, Jaroslav Luksch ICTON 2009, Ponta Delgada Brno University of Technology, Institute of Physical Engineering

CONTENTS 1. Introduction 2. Formulation 3. Numerical examples 4. Conclusion

INTRODUCTION TMM [Y. Dumeige, P. Féron: Dispersive tristability in microring resonators, Physical Review E, vol. 72, pp , 2005] - numerical solution of nonlinear equation; - solution is in frequency domain only; nonlinear resonant structures

INTRODUCTION FD-TD - high spatial resolution required => time-consuming calculation => advanced algorithms [A. Christ, J. Fröhlich, N. Kuster.: Correction of numerical phase velocity errors in nonuniform FDTD meshes, IEICE Trans. Commun., vol. E85-B, pp , 2002] …

CONTENTS 1. Introduction 2. Formulation 3. Numerical examples 4. Conclusion

FORMULATION inputoutput A racetrack microring resonator side-coupled to a waveguide.

FORMULATION outside of the coupling region inside of the coupling region Propagation of optical pulses inputoutput

FORMULATION Boundary conditions inputoutput

FORMULATION Using explicit finite-difference scheme where,,,

FORMULATION Von Neumann stability analysis applied: Courant condition Additional criterion,,

FORMULATION 1)In typical calculations:,, 2)

CONTENTS 1. Introduction 2. Formulation 3. Numerical examples 4. Conclusion

NUMERICAL EXAMPLES inputoutput

NUMERICAL EXAMPLES inputoutput

CONTENTS 1. Introduction 2. Formulation 3. Numerical examples 4. Conclusion

CONCLUSIONS a simple finite-difference scheme for solution of nonlinear coupled equations has been developed; the technique has been applied to Kerr-nonlinear structure; stability criterions have been presented; comparison with the TMM has been presented; easy inclusion of nonlinear effects.

Thank you for your attention!