![]() Thuerey’s team also sought to improve the speed and quality with which smoke effects could be simulated by using a library of pre-generated data.īy taking the starting positions and velocity of smoke particles, a neural network builds a simplified model of the expected flow. “If doctors get immediate feedback about pressure distributions in a patient’s vein, they could adjust what they do in real time.” Smoke signals ![]() “You have the case of a marker injected into veins, where you can see the motion of a known quantity in an unknown field,” he explains. We developed machine learning based on data sets, to be able to solve these different problems.” Thuerey adds his team is among the first to connect these physical problems with machine learning algorithms.īeing able to understand the underlying physical processes affecting a fluid, from footage of its movement, has a range of applications, such as analysing airflow over aircraft wings, or the forces generating weather systems.Īnother application is in medicine, notes Thuerey. “Naturally we harnessed development in AI over recent years. “The original proposal was to work with data, observational and simulated, to figure out what happens,” says Thuerey. Neural networks were fed data on fluid movements such as smoke density and flow velocity, and allowed to come up with their own descriptions of the physics involved. To achieve this, Thuerey and his colleagues decided early on to pursue a machine learning approach. The goal was to be able to do this only from two-dimensional images. “For example, we’d like to have a cloud of smoke rising somewhere, and be able to predict what the underlying air movements are doing,” explains project coordinator Nils Thuerey, who is based at the Technical University of Munich. The project set out to create a system that could capture the underlying physics of real-world examples. Typically, fluid models are constructed to mimic real-world physics, giving researchers the ability to run simulations that are quicker and cheaper to carry out than physical experiments. The EU-funded realFlow project sought to improve the connection between fluid models and the real world, using a machine learning approach. Understanding how fluids move in three-dimensional space is central to a range of industries from medicine to engineering, and even creating convincing special effects in film.
0 Comments
Leave a Reply. |
AuthorWrite something about yourself. No need to be fancy, just an overview. ArchivesCategories |