Optisystem 13: A Powerful Tool for Optical Communication System Engineers, Researchers and Students

Optisystem 13 Free Download With Crack And 517

If you are looking for a comprehensive design suite that enables you to plan, test and simulate optical links in the transmission layer of modern optical networks, you might be interested in Optisystem 13. This software includes transmitters, receivers and DSP components for end-to-end 16-QAM, DP-16-QAM and DP-QPSK coherent optical system design and performance analysis. In this article, we will show you what Optisystem 13 is, why you should use it, and how to download it for free with crack and 517.

Optisystem 13 Free Download With Crack And 517

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Introduction

What is Optisystem 13?

Optisystem 13 is the latest version of Optiwave's flagship software for optical communication system design and simulation. It was released in April 2020 and includes many important enhancements over the previous versions. Optisystem 13 allows users to design and optimize complex optical systems using a variety of components, models, algorithms and visualizers. It also supports the analysis of various modulation formats, such as BPSK, QPSK, 8PSK, 16PSK, 16QAM and 64QAM.

Why use Optisystem 13?

Optisystem 13 is a powerful tool for optical communication system engineers, researchers and students who want to explore the latest technologies and trends in the field. It can help you to:

• Design and optimize optical systems for different applications, such as long-haul transmission, metro networks, access networks, data centers, etc.

• Simulate the performance of optical systems under various conditions, such as noise, dispersion, nonlinearities, polarization effects, etc.

• Evaluate the impact of different components and models on the system performance, such as lasers, modulators, detectors, filters, amplifiers, etc.

• Compare different modulation formats and coding schemes for achieving higher spectral efficiency and data rates.

• Visualize the results of your simulations using various graphs, charts, tables and animations.

How to download Optisystem 13 for free with crack and 517?

If you want to download Optisystem 13 for free with crack and 517, you need to follow these steps:

• Go to this link: https://optiwave.com/download-1/optisystem-64-bit-13-0-1-web-update/

• Fill in your name and email address and click on "Download Now".

• You will receive an email with a link to download the software installer.

• Download the installer and run it on your computer.

• Follow the instructions on the screen to install Optisystem 13.

• After the installation is complete, go to this link: https://crackzsoft.me/optiwave-optisystem-14-2-x64-free-download/

• Download the crack file and extract it on your computer.

• Copy the crack file (OptiSystem.exe) and paste it into the installation folder of Optisystem 13 (usually C:\Program Files\Optiwave Software\OptiSystem\).

• Replace the original file with the crack file.

• Run Optisystem 13 from your desktop or start menu.

• You will see a message saying "License not found". Click on "OK".

• You will see another message saying "Enter license number". Enter "517" and click on "OK".

• You have successfully activated Optisystem 13 for free with crack and 517.

Features of Optisystem 13

Optisystem 13 includes many new features that enhance its functionality and usability. Some of these features are:

Universal DSP component

This component provides a complete suite of DSP algorithms for analyzing a multitude of modulation formats. It includes a new nonlinear compensation model that can mitigate the effects of fiber nonlinearities on signal quality. It also supports adaptive equalization, carrier phase estimation, symbol timing recovery, polarization demultiplexing, frequency offset estimation and correction, constellation demapping and decoding.

Decision and PAM Decision components

These components allow users to perform decision operations on different modulation formats. The Decision component supports BPSK, QPSK, 8PSK, 16PSK, 16QAM and 64QAM. The PAM Decision component supports m-PAM systems. These components can be used to evaluate the bit error rate (BER) and symbol error rate (SER) of optical systems.

Optical Sources Library

This library contains several updates and improvements to the existing optical source components. It includes:

• A new DFB Laser model that uses couple mode theory to more accurately calculate the longitudinal modes present in the DFB cavity.

• A new Fabry-Perot Laser model that uses transmission line theory to more realistically simulate the dynamics of FP lasers.

• A new Empirical Laser Measured component that allows users to match their simulations with manufacturer and lab measurement data of semiconductor lasers.

• A new Set OSNR component that allows users to set up accurate OSNR sweeps for testing system performance under different noise levels.

Analog to Digital and Digital to Analog converters

These components allow users to simulate the effects of analog-to-digital (ADC) and digital-to-analog (DAC) converters on optical signals. They can be used to model quantization errors, sampling rates, resolution bits, bandwidths and other parameters of ADCs and DACs. They can also be used to design and optimize laser/modulator drivers for high-speed optical systems.

90 Deg Optical Hybrid component

This component allows users to design and analyze coherent homodyne receiver systems. It can split an incoming signal into four outputs with different phase shifts (0 ,90 ,180 ,270 ). It can also combine two signals with different polarizations into one output. It can be used in conjunction with balanced photodetectors (BPDs) and DSP components to implement coherent detection schemes.

PIN and TIA components

These components allow users to model high-speed photodetectors (>25 Gb/s) more effectively. They include updated models for PIN photodiodes (PINs) and transimpedance amplifiers (TIAs). They can be used to simulate responsivity curves , frequency responses, noise figures and other characteristics of PINs and TIAs.

Optical and Electrical Filter Libraries

These libraries contain several updates and improvements to the existing optical and electrical filter components. They include:

• A new Nyquist Filter component that can be used to design and implement Nyquist pulse shaping filters for high spectral efficiency systems.

• A new Raised Cosine Filter component that can be used to design and implement raised cosine pulse shaping filters for various modulation formats.

• A new Root Raised Cosine Filter component that can be used to design and implement root raised cosine pulse shaping filters for various modulation formats.

• A new Gaussian Filter component that can be used to design and implement Gaussian pulse shaping filters for various modulation formats.

• A new Super Gaussian Filter component that can be used to design and implement super Gaussian pulse shaping filters for various modulation formats.

• A new Bessel Filter component that can be used to design and implement Bessel low-pass filters for various applications.

• A new Butterworth Filter component that can be used to design and implement Butterworth low-pass filters for various applications.

• A new Chebyshev Filter component that can be used to design and implement Chebyshev low-pass filters for various applications.

Multi-threading support for parameter sweeps

This feature allows users to greatly accelerate calculation times when performing multiple iteration analysis of Optisystem projects on multi-core CPU platforms. It enables users to run parameter sweeps in parallel using multiple threads, thus reducing the simulation time significantly. Users can specify the number of threads to use and the range of parameters to sweep in the Parameter Sweep dialog box.

Lightwave Analyzer visualizer

This visualizer allows users to measure the responsivity and frequency response of a multitude of devices under test (DUT) including PINs, TIAs, lasers, optical modulators, etc. It can also measure the optical spectrum, eye diagram, constellation diagram, BER/SER, Q-factor and other parameters of optical signals. Users can connect any optical or electrical signal to the input port of the Lightwave Analyzer and select the measurement mode and settings in the visualizer window.

Conclusion

Optisystem 13 is a state-of-the-art software for optical communication system design and simulation. It offers a wide range of features and components that enable users to create and optimize complex optical systems for various applications and scenarios. It also supports the analysis of different modulation formats and coding schemes for achieving higher data rates and spectral efficiency. Optisystem 13 is a valuable tool for optical communication system engineers, researchers and students who want to learn more about the latest developments and trends in the field.

FAQs

• What are the system requirements for Optisystem 13?

Optisystem 13 requires a Windows operating system (Windows 7 or higher), a 64-bit processor, at least 4 GB of RAM, at least 1 GB of free disk space, a graphics card with OpenGL support, and an internet connection for activation.

• How much does Optisystem 13 cost?

Optisystem 13 is not a free software. It has different pricing plans depending on the license type, duration and number of users. You can contact Optiwave Corporation for more details on their website: https://optiwave.com/contact-us/

• Is Optisystem 13 compatible with other software?

Optisystem 13 can import and export data from/to other software such as MATLAB, Excel, OptiSPICE, OptiFDTD, etc. It can also communicate with other software using COM/DCOM or TCP/IP protocols.

• What are some of the applications of Optisystem 13?

Optisystem 13 can be used for various applications such as:

• Long-haul transmission systems using coherent detection and DSP techniques.

• Metro networks using WDM or OFDM technologies.

• Access networks using PON or FSO technologies.

• Data centers using VCSELs or silicon photonics.

• Sensor networks using fiber Bragg gratings or microresonators.

• Lidar systems using pulsed lasers or modulators.

• Where can I find more information about Optisystem 13?

You can find more information about Optisystem 13 on their website: https://optiwave.com/products/system-and-amplifier-design/optisystem/ You can also access their online help, tutorials, examples, webinars and forums on their website.