Experience Science in Action with Digital Dynamics StudioTM
Hands-on STEM learning with real-time computational fluid dynamics simulations in the classroom.
Discover MoreAbout Digital Dynamics Studio
New Capabilities for Experimentation and Analysis
Digital Dynamics Studio is an interactive computational fluid dynamics (CFD) simulation platform that enables real-time experimentation of a wide variety of scientific and engineering applications. Students in STEM fields will have the opportunity to engage in real-time simulation, modeling, and analysis that can deepen their understanding of complex scientific concepts. Through hands-on experimentation, students can explore cutting-edge technologies and methodologies that enhance their problem-solving skills and foster the critical thinking abilities needed for success in the ever-evolving fields of science and engineering.
Core Offerings
Explore Key Features
Real-Time Fluid Simulations
Advanced computational techniques are used to enable adaptive and accurate simulation of a wide variety of problems in 2D at interactive frame-rates.
Easy-to-Use
Simulations are carried out directly within the browser (i.e. right here) with fully integrated modeling, simulation, and visualization workflows.
Full Documentation
Access extensive documentation where all topics needed by the student are covered. This includes overviews, tutorials, and suggested student experiments.
The Power of Digital Dynamics Studio
Advanced Scientific Analysis with Computational Fluid Dynamics
Shown below are several examples of physical phenomena and applications simulated using the Digital Dynamics Studio. Each video highlights the capabilities of the simulation platform, its features, and the type of CFD analysis that can be performed by students. As can be seen here, the tool is highly flexible and able to model a wide variety of physics and application domains. The advanced visualization features of the simulation engine are also prominently highlighted throughout these examples.
Magnus Effect
Airflow past a spinning cylinder is simulated to demonstrate the Magnus Effect. This effect produces lift on a spinning cylinder when placed within cross-flow.
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Natural Convection
Natural convection flows are simulated under varying conditions. Both linear and circular domains are modeled at a variety of Rayleigh numbers.
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Airflow Past an Airfoil
Airflow past an airfoil at 10 degrees angle-of-attack is shown at a Reynolds Number of 1,000. Various flow features as well as the adaptive unstructured mesh are highlighted.
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