Products - Design Software for Photonics by Optiwave
Design the future Optical Systems
Optiwave Corporation's suite of design and simulation software maximizes the efficiency and effectiveness of our customer's optical networks, subsystems and components to help bring customer's vision to light.
Optiwave's Software solution are employed by over 500 leading high-technology businesses, research institutions, universities and government agencies in 40 countries worldwide
OptiSystem is a comprehensive software design suite that enables users to plan, test, and simulate optical links in the transmission layer of modern optical networks.In an industry where cost effectiveness and productivity are imperative for success, the award winning OptiSystem can minimize time requirements and decrease cost related to the design of optical systems,links, and components. OptiSystem is an innovative,rapidly evolving, and powerful software design tool that enables users to plan, test, and simulate almost every type of optical link in the transmission layer of a broad spectrum of optical networks from LAN, SAN, MAN to ultra-long-haul. It offers transmission layer optical communication system design and planning from component to system level, and visually presents analysis and scenarios. Its integration with other Optiwave products and design tools of industry leading electronic design automation software all contribute to OptiSystem speeding your product to market and reducing the payback period.
OptiSystem 13.0 - New version now available
The most comprehensive optical communication design suite for optical system design engineers is now even better with the release of OptiSystem version 10, available in 32-bit and TRUE 64-bit editions.
Interface with Popular Design Tools
Some Specific Benefits
>> Four-wave Mixing, Stimulated Brillouin Scattering (SBS),
Self-Phase Modulation, Cross-Phase Modulation >> Stimulated Raman Scattering, and full bi-directional capabilities. >>MLSE (Maximum Likelihood Sequence Estimate),
advanced component using the Viterbi algorithm >> A robust library of multimode fiber models, including Parabolic-Index and Measured-Index profile. >> The most advanced optical amplifier design library available. >> Provides automatic parameter sweep and optimization
>> Integrates with the family of Optiwave products
Comprehensive Amplifier Design Suite
Full Multi-mode Edition
Optiperformer -- Versatile tool
Coherent Optical OFDM
100 Gbps DP-QPSK with DSP
Free Space Optics
Inter Satellite Communication
Optical Hybrid & rare earth elements based fiber models
OptiSPICE is the first circuit design software for analysis of integrated circuits including interactions of optical and electronic components. It allows for the design and simulation of opto-electronic circuits at the transistor level, from laser drivers to transimpedance amplifiers, optical interconnects and electronic equalizers. OptiSPICE produces self-consistent solutions of opto-electronic circuits that contain feedback spanning both optical and electrical parts. OptiSPICE is a fully-integrated solution for parameter extraction, schematic capture, circuit simulation and waveform analysis.
Previously the ability for a single software package to tightly model optical-electrical integration, thermal coupling and various optical effects ( interference, reflection and multiple carrier frequencies) was non-existent.
OptiSPICE package includes complimentary modules of
Laser Parameter Extractor
Multimode Fiber Parameter Extractor
Modulator Parameter Extractor
Filter Parameter Extractor
Significantly reduce product development costs and .boost productivity through OptiSPICE comprehensive design environment to simulate optical and electrical circuits in one simulation engine.
Run state-of-the-art transient time domain, small-signal frequency, and noise analysis to accurately predict behaviour of advanced opto-electronic circuits.
OptiSPICE Schematics offers direct schematic entry in an intuitive graphical user interface. It allows for greater ease of schematic capture, parameter specification, waveform probing and usage.
Waveform analysis using OptiSystem for complex post-processing functionality. Advanced visualization tools produce OSA Spectra, signal chirp, eye diagrams, polarization state, constellation diagrams and much more.
Includes parameter extraction tools for OptiSPICE model creation. From measurement data, parameter extractors are used to find the best set of OptiSPICE model parameters to fit the measurement.
OptiFDTD enables you to design, analyze and test modern passive and nonlinear photonic components for wave propagation, scattering, reflection, diffraction, polarization and nonlinear phenomena. The core program of OptiFDTD is based on the Finite-Difference Time-Domain (FDTD) algorithm with second-order numerical accuracy and the most advanced boundary conditions - Uniaxial Perfectly Matched Layer (UPML).
Presents global overview of photonics problems & True Parellel performance
Provides broad material choice & offers extensive excitation selection
Plane Wave Expansion band solver for photonic crystals
Summary of Features:
Sources: A variety of sources includes Waveguide mode using Optimode, Gaussian Beam Input, Plane Wave, Point Source- Dipole
Single Wavelength(CW) source, Pulsed source, Linear or circular Polarizations.
Dielectric (loseless & lossy) materials, (n,k) direct entry or Sellmeier model for glasses, Isotropic & Anisotropic Media
Dispersive (Lorentz, Drude & Lorentz-Drude) , Non-Linear Media (2nd & 3rd order, Kerr & Raman), Perfect conductor material
Boundary Conditions: Uniaxial Perfectly Matched layers (UPML), Perfect Electric Conduator (PEC), Perfect Magnetic Conductor (PMC)
Periodic Boundary Conditions (PBC)
Geometry: Straight & Tilted waveguides , Ring, Arc, Circle, Ellipse & Parabolic , Exponential Waveguides All with Taper functions
3D shapes with clipping features, Photonic crystal Lattice editor, Import from 3rd party CAD layout software, Exports masks
Simulator & Detection:
2D TM or TE, 3D simulations, Cluster computing, hybrid multithreading , Full 64 bit, MPI engine on Linux clusters
Point detectors (temporal & spectral), Line & Area detectors (DFT spectra) , Mode, Polarised Power & Poynting Vector analysis
Few of its vast range of applications includes
OptiBPM is a comprehensive CAD environment used for the design of complex optical waveguides. Perform guiding, coupling, switching, splitting, multiplexing, and demultiplexing of optical signals in photonic devices.
OptiBPM can improve design engineers’ productivity, reduce risk, and lower overall costs related to design of waveguide solutions. OptiBPM’s high-value functionality includes powerful integration capabilities with our award-winning optical communication system software, OptiSystem, and with Design Workshop’s dw-2000, a mask layout physical design and verification software.
Design optical splitters, combiners, couplers, multiplexers, and modulators.
OptiGrating uses the Coupled Mode Theory to model the light and enable analysis and synthesis of gratings.A complex Grating is approximated by a sequence of uniform segments, and analyzed by connecting the segments with the well-known Transfer Matrix Method. This gives the designer the information needed to test and optimize grating designs. india
WDM add/drop, narrow and broadband fiber and waveguide filters
Fiber Bragg reflectors
EDFA gain flattening elements
Dispersion compensators for fiber communications
Sideband suppression using grating apodization
Fiber and waveguide sensors
Long Period Gratings with coupling to cladding modes
The optimal design of a given optical communication system depends directly on the choice of fiber parameters. OptiFiber uses numerical mode solvers and other models specialized to fibers for calculating dispersion, losses, birefringence, and PMD.Meshless Mode Solvers for LP and Vector Modes:Optical fibers may consist of an arbitrary number of concentric layers of lossless materials, and graded index fibers can be approximated using a sequence of constant index layers. OptiFiber 2.0 mode solvers find an exact solution based on matching boundary conditions at layer boundaries instead of relying on meshes to approximate the structure.These advanced mode solvers should be especially useful for multimode fiber calculations, where there are many modes in the spectrum.Another advantage of the meshless mode solver is the calculation of fields far from the fiber. Meshing introduces finite difference errors of a certain level, and fields weaker than the differencing error cannot be calculated. The meshless mode solvers, on the other hand, have the correct asymptotic behavior far from the fiber, and can calculate fields of magnitude 10-15 or less.This feature is in addition to the existing mode solvers in OptiFiber.
We offers introductory courses for all products. Trainers, who are expert engineers, focus on your goals and how you can best utilize Optiwave tools to achieve them. Our two day short courses allow for a ‘hands on’ approach on learning how to use Optiwave tools to their best capabilities.
OptiSYSTEM Fundamentals and Design Techniques
OptiFDTD Fundamentals and Design Techniques
OptiBPM Fundamentals and Design Techniques
OptiFiber & OptiGrating Fundamentals and Design Techniques