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.
Categories
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
Join us at the AngelTech Live III
March 15, 2021
Join us at the AngelTech Live III on 12th April 2021 Registration is open and free Here The drive to miniaturization, battery power, high speed, sensing, imaging, and advanced computational processing means that photonic integration will grow, and grow quickly. Cramming discrete, individual components in a small box is going away, in fact, just like…
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