UltrafastPED said:Here is a description from a thesis which used this method:
http://www.phys.ksu.edu/personal/washburn/pdf/washburn_thesis_chapter4.pdf
Here is a discussion of the algorithm:
http://en.wikipedia.org/wiki/Split-step_method
UltrafastPED said:Here is a description from a thesis which used this method:
http://www.phys.ksu.edu/personal/washburn/pdf/washburn_thesis_chapter4.pdf
Here is a discussion of the algorithm:
http://en.wikipedia.org/wiki/Split-step_method
UltrafastPED said:The graphs to be shown would be the pseudo-spectra; the actual problem that you are working on will determine what needs to be shown.
I cannot help you with Matlab.
UltrafastPED said:Here's a reference: http://en.wikipedia.org/wiki/Pseudo-spectral_method
Nonlinear optics is the study of the interaction between light and matter in materials that exhibit nonlinear optical properties. These materials can produce optical effects that are not seen in linear materials, such as frequency doubling and optical parametric amplification.
The split method is a technique used in nonlinear optics experiments to separate and analyze the components of a nonlinear optical process. It involves splitting a beam of light into two paths, with each path experiencing a different intensity or polarization. By comparing the output from each path, researchers can determine the nonlinear response of the material being studied.
The split method is used in research to investigate the nonlinear properties of materials, such as crystals and liquids. By controlling the intensity and polarization of the light in each path, researchers can measure the nonlinear response of the material and determine its optical properties. This information can then be used to develop new technologies and applications in fields such as photonics and telecommunications.
The split method offers several advantages in nonlinear optics research. It allows for precise control and measurement of the nonlinear response of materials, which is crucial for understanding their properties. Additionally, the split method is a non-invasive technique, which means it does not damage the material being studied. This makes it a safe and effective tool for studying a wide range of materials and applications.
The split method can provide valuable information about the nonlinear response of materials, such as their nonlinear susceptibility and phase-matching conditions. This information can be used to design and optimize nonlinear optical devices, such as lasers and optical switches. Additionally, the split method can also reveal new phenomena and behaviors in materials that can lead to advancements in the field of nonlinear optics.