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Optiwave Systems Inc.
光通訊系統模擬設計

完整的 6 大模組,從主動元件、被動元件到光通訊系統

Optiwave is the emerging leader in the development of innovative software tools for the design, simulation, and optimization of components, links, systems and networks for the dynamically growing fields in photonics nanotechnology, optoelectronics, optical networks and other photonic applications.

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OptiSystem

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.

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OptiSPICE

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.

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OptiFDTD

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 condition – uniaxial perfectly matched layer (UPML) boundary condition. 

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OptiBPM

OptiBPM can combine channel, fiber, and diffused waveguides into a single layout. A simple menu selection allows a layout to be simulated in either 2D or 3D. Integration with OptiSystem delivers continuity in simulation from the waveguide to the system or subsystem level. Complex field data transfer between OptiFDTD and popular ray tracing tools, allows OptiBPM designers to incorporate free space optical elements.

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OptiFiber

The optimal design of a given optical communication system depends directly on the choice of fiber parameters. Dimensions of the fiber cross-section, material composition, and refractive index profile all influence important linear and non-linear phenomena. OptiFiber uses numerical mode solvers and other models specialized to fibers for calculating dispersion, losses, birefringence, and PMD.

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OptiGrating

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.

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