Encoding the volumetric information already in the design mesh drastically simplifies and speeds up the mesh generation process for simulation. Volumetric modeling operations allow designing 3D objects in similar ways as with surface-based modeling tools, while automatic checks and modifications of inner control points ensure consistency during the design process. Instead of modeling 3D objects as surface models, we use a volumetric subdivision representation. After drawing the examples in the course with me, if you practice at least once to make a similar example by yourself, you will become a user who really understands the basics of SubD modeling in Rhino 7.In this paper, we present a novel approach for a tighter integration of 3D modeling and physically-based simulation. I aim to repsresent the logic of the working processes to the students and help you to reach a level of mastery where you can adapt the knowledge you have gained from my courses to different problems you will encounter in your career. There is a basic quality that I want my courses to have. If the course reaches to a certain amount of purchases (maybe around 100 students, maybe less) I will add at least 2 more projects and cover the remaining topics of SubD modeling in Rhino. You can purchase the course if you want to support me to make this course a more comprehensive SubD modeling content. I'm keeping all the lessons open to free access.
So, please feel free to give feedback about my communication skills or about anything you want to share about the course. This course is my first in English and is a test bed for my upcoming courses in this language. I'm an industrial designer who had the chance to experience being an instructor for design softwares and continued to enjoy sharing his knowledge since 2018. Knowledge you will gain in this course will create a good starting point for you to understand SubD processes in Rhino. In this course, you will learn the basic mechanics of SubD modeling in Rhino 7 by drawing a pouff.
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