Unlocking Euclidean Problems with Isotropic Initialization
The seminar introduces a novel, general approach for solving challenging constraint systems in Euclidean geometry problems by leveraging analogous, structure-preserving simplifications found in isotropic geometry to initialize and guide optimization algorithms.
Overview
Many problems in Euclidean geometry, arising in computational design and fabrication, amount to a system of constraints, which is challenging to solve. We suggest a new general approach to the solution, which is to start with analogous problems in isotropic geometry. Isotropic geometry can be viewed as a structure-preserving simplification of Euclidean geometry. The solutions found in the isotropic case provide insight and can initialize optimization algorithms to solve the original Euclidean problems. We illustrate this general approach with three examples: quad-mesh mechanisms, composite asymptotic-geodesic gridshells, and asymptotic gridshells with constant node angle.
Presenters
Brief Biography
Mikhail Skopenkov has been a research scientist at the CEMSE Division at KAUST since 2022 and an associate professor at HSE University in Moscow since 2014. He earned a master's degree and doctorate from Lomonosov Moscow State University as well as a habilitation from HSE University. He has published 30 research papers, 10 pedagogical ones, and 4 books.
Related People
Related Researchers
Mikhail Skopenkov
- Research Scientist, Computer Science