# This is How You Simulate Making Pasta 🍜 ## Метаданные - **Канал:** Two Minute Papers - **YouTube:** https://www.youtube.com/watch?v=uVC5WowQxD8 - **Дата:** 24.09.2019 - **Длительность:** 4:07 - **Просмотры:** 113,837 - **Источник:** https://ekstraktznaniy.ru/video/14249 ## Описание ❤️ Check out Linode here and get $20 free credit on your account: https://www.linode.com/papers 📷 Check us out on Instagram: https://www.instagram.com/twominutepapers/ 📝 The paper "A Multi-Scale Model for Coupling Strands with Shear-Dependent Liquid " is available here: http://www.cs.columbia.edu/cg/creamystrand/ ❤️ Pick up cool perks on our Patreon page: https://www.patreon.com/TwoMinutePapers 🙏 We would like to thank our generous Patreon supporters who make Two Minute Papers possible: Alex Haro, Andrew Melnychuk, Angelos Evripiotis, Anthony Vdovitchenko, Brian Gilman, Bruno Brito, Bryan Learn, Christian Ahlin, Christoph Jadanowski, Claudio Fernandes, Daniel Hasegan, Dennis Abts, Eric Haddad, Eric Martel, Evan Breznyik, Geronimo Moralez, James Watt, Javier Bustamante, John De Witt, Kaiesh Vohra, Kasia Hayden, Kjartan Olason, Levente Szabo, Lorin Atzberger, Lukas Biewald, Marcin Dukaczewski, Marten Rauschenberg, Matthias Jost,, Maurits van Mastrigt, Michael Albrecht, Michael Jense ## Транскрипт ### [] Dear Fellow Scholars, this is Two Minute Papers with Károly Zsolnai-Fehér. Fluid simulation is a mature research field within computer graphics with amazing papers that show us how to simulate water flows with lots of debris, how to perform liquid-fabric interactions, and more. This new project further improves the quality of these works and shows us how thin, elastic ### 1/8x replay [0:23] strands interact with oil paint, mud, melted chocolate, and pasta sauce. There will be plenty of tasty and messy simulations ahead, not necessarily in that order, so, make sure to hold on to your papers, just in case. Here you see four scenarios of these different materials dripping off of a thin strand. So, why are these cases difficult to simulate? The reason why it’s difficult, if not flat out impossible because the hair strands and the fluid layers are so thin, it would require a simulation grid that is so microscopic, or in other words, we would have to perform our computations of quantities like pressure and velocity on so many grid points, it would probably take not from hours to days, but from weeks to years to compute. I will show you a table in a moment where you will see that these amazingly detailed simulations can be done on a grid of surprisingly low resolution. As a result, our simulations also needn’t be so tiny in scale with one hair strand and a few drops of mud or water. They can be done on a much larger scale, so we can marvel together at these tasty and messy simulations, you decide which is which. I particularly liked this animation with the oyster sauce because you can also see a breakdown of the individual ### 1/4x replay [1:46] elements of the simulation. Note that all of the interactions between the noodles, the sauce, the fork, and plate have to be simulated with precision. Love it. And now, the promised table. Here you can see the delta x that means how fine the grid resolution is, which is in the order of centimeters, and not micrometers. That is reassuring, and don’t forget that this work is an extension to the Material Point Method, which is a hybrid simulation method that both uses grids and particles. And, sure enough, you can see here that it simulates up to tens of millions of particles as well, and the fact that the computation times are still only measured in a few minutes per frame is absolutely remarkable. Remember, the fact that we can simulate this at all is a miracle. Now, this was run on the processor, and a potential implementation on the graphics card ### Chocolate "Dog" [2:42] could yield us significant speedups, so I really hope something like this appears in the near future. Also, make sure to have a look at the paper itself, which is outrageously well written. If you wish to see more from this paper, make sure to follow us on Instagram, just search for Two Minute Papers there or click the link in the description. Now, I am still working as a full-time research scientist at the Technical University of Vienna, and we train plenty of neural networks during our projects, which requires a lot of computational resources. Every time we have to spend our time maintaining these machines, I wish we could use Linode. Linode is the world’s largest independent cloud hosting and computing provider. If you feel inspired by these works and you wish to run your experiments or deploy your already existing works through a simple and reliable hosting service, make sure to join over 800,000 other happy customers and choose Linode. 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