The concluding part of our discourse will show both the complexity and the flexibility of the presented modeling improvements. The OptiSystem schematic layout brings a new vision of the optical circuit behavior. Any advanced photonic circuit may be further studied as a set consisting of separated fundamental components. As we will also see, the use of the OptiSystem platform extends the simulation possibilities dramatically, because of a possible entering of various photonic and even electronic simulation tools.
OptiBPM Manuals
- OptiBPM Tutorials
- OptiBPM Applications
- BPM Technical Background
- Introduction
- Slowly Varying Envelope Approximation
- Differential Equations of BPM
- Semi-Vector and Scalar BPM
- Crank-Nicholson Method and Scheme Parameter
- ADI
- Boundary Conditions for BPM
- Perfectly Matched Layer (PML)
- Wide-Angle Beam Propagation Method
- Finite Difference Beam Propagation Method (FD-BPM) with Perfectly Matched Layers
- Finite Difference Beam Propagation Method (FD-BPM) with Transparent Boundary Conditions
- Finite Element Beam Propagation Method (FE-BPM) with Perfectly Matched Layers
- Wide-Angle Beam Propagation Method based on Pade Approximant Operators
- Fresnel Approximation (Pade 0th Order)
- Wide Angle (WA), Pade(1,1)
- Wide Angle (WA), Pade(2,2)
- Wide Angle (WA), Pade(3,3)
- Wide Angle (WA), Pade(4,4)
- References
- Conformal Mapping Regions
- Diffusion in Lithium Niobate
- Electro-optic Effect
- Scattering Data
- Introduction
- Modeling of the Optical Components – Survey of Methods
- Circuit Complexity Introduction
- Huge BPM Devices (“mux/demux”)
- Multidirectional BPM Device
- Devices Consisting of the Combination of BPM & Gratings (“Add/Drop”)
- Devices out of Scope of the BPM Technique (ring resonator)
- Scattering Data Approach
- Implementation with OptiSystem
- Solutions using OptiSystem
- Four Channel Mach-Zehnder Multi/Demultiplexer
- The MZI – ‘Loopy’
- Add/Drop Bragg MZI
- Ring Resonator
- References
- Non-linear BPM Algorithm
- Manual Calculation Method
- Vectoral Beam Propagation for Anisotropic Waveguides
- Vectoral Modal Analysis for Anisotropic Waveguides
- Fiber Mode Solvers
- Finite Difference Mode Solver
- Lesson 1: Getting Started
- Before Installation
- Installation
- Introduction to OptiBPM
- Introduction to Optical Waveguides
- Quick Start
- GUI Main Parts
- How to use OptiBPM
- Defining Materials
- Defining 2D and 3D Channel Profiles
- Defining the Layout Settings
- Creating a Basic Project
- Inserting the Input Plane
- Running the Simulation
- Selecting the Master Library Path
- Lesson 2: Create a Simple MMI Coupler
- Lesson 3: Create a Single-Bend Device
- Lesson 4: Create an MMI Star Coupler
- Lesson 5: Wavelength Scripting with VB Script
- Lesson 6: Design a 3dB Coupler using VB Script
- Lesson 7: Applying Predefined Diffusion Processes
- Lesson 8: 3D OptiMode Solver - COST Project Waveguide
- Lesson 9: Create a Chip-to-Fiber Butt Coupler
- Lesson 10: Electro-Optic Modulator
- Lesson 11: Integrated Optical Circuit Simulation using OptiBPM and OptiSystem - Scattering Data Export
- Lesson 12: Scan the Refractive Index (RI)
- Lesson 13: Applying User-defined Diffusion Profiles
- Lesson 14: Mach-Zehnder Interferometer Switch
Simulating the Future of Networks with Optiwave
October 21, 2019
Optiwave Systems is an Ottawa based software company, boasting a robust variety of photonic design tools, which it provides to hundreds of leading high-technology institutions. Founded in 1994 and incorporated in 2005, the company has a well-established community of over one thousand users in over seventy countries. Optiwave has come to CENGN in order to validate…
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