Optiwave Optisystem [portable] Jun 2026
: Capable of modeling WDM, DWDM, Free Space Optics (FSO), Passive Optical Networks (PON), and coherent systems.
Optiwave continues to invest heavily in emerging technologies. Recent release notes and webinar content indicate that the company is prioritizing:
For calculating Q-factor, BER, and eye diagrams.
Simulating a network prevents costly deployment errors and minimizes the reliance on physical testbeds and expensive optical spectrum analyzers. optiwave optisystem
OptiSystem is built on a hierarchical, modular architecture that mimics real-world optical engineering workflows. It utilizes a graphical user interface (GUI) to manage complex system layouts, data visualization, and component scripting.
New users can download a fully functional 30‑day trial version from the official Optiwave website. After registration, the trial provides access to all features, allowing engineers to evaluate the software on real design projects before making a purchase decision. Academic pricing and flexible licensing—including monthly leases and perpetual licenses—are available.
Optiwave has been serving the photonics community since its founding in Ottawa, Canada, in 1994. Over three decades, the company has licensed its software to more than 1,000 corporations, government agencies, and academic institutions in more than 80 countries. : Capable of modeling WDM, DWDM, Free Space
OptiSystem (by Optiwave) is a professional optical communication system design and simulation software used to model, simulate, analyze, and optimize photonic systems and components — including fiber-optic links, DWDM systems, optical amplifiers, modulators, detectors, and more.
To calculate Bit Error Rate (BER) and Q-factor automatically.
Simulate the delivery of cable television over fiber, focusing on minimizing distortion and noise. Simulating a network prevents costly deployment errors and
At the heart of OptiSystem is a time-domain and frequency-domain engine. Most simulations use a combination of (for high-speed signals) and Sampled Signals . The engine solves the Non-Linear Schrödinger Equation (NLSE) for fiber propagation, accounting for chromatic dispersion (CD), polarization mode dispersion (PMD), and Kerr non-linearities.
Double-clicking components in newer versions of the simulator (v17+) provides an overview of the literature used for modeling and simulation, acting as a "standard book help menu". Conclusion
