It requires the definition of the initial input embedded beam properties and its M2 value. The advantage is it allows you to enter both ideal and mixed-mode (M2>1) Gaussian beam and displays beam data as it propagates surface by surface in your optical system. This feature computes ideal and mixed-mode Gaussian beam data as a given input beam propagates through the lens system. The Paraxial Gaussian Beam analysis is an interactive feature that works as a “calculator” that quickly computes Gaussian beam characteristics. You can find the tool at Analyze.Lasers and Fibers.Gaussian Beams…Paraxial Gaussian Beam. It shows how to set up the analysis to optimize for the smallest laser beam size. This blog post introduces the Paraxial Gaussian Beam analysis tool. Physical Optics Propagation (POP) models laser beam by propagating a coherent wavefront, which allows very detailed study of arbitrary coherent optical beams.It models Gaussian beam and reports various beam data, including beam size and waist location as it propagates through a paraxial optical system. It models beam propagation using geometrical ray tracing. OpticStudio Sequential Mode provides three tools to model Gaussian beam propagation: Discover what tools are available, how to set up, analyze laser beam propagation, and optimize for the smallest beam size in a simple singlet lens system in OpticStudio sequential mode. In a blog post, you will learn the key steps in modeling laser beam propagation in OpticStudio.
0 kommentar(er)
