Universidad de Zaragoza
Abstract
Standard simulation in classical mechanics is based on the use of two very different types of equations. The first one, of axiomatic character, is related to balance laws (momentum, mass, energy, …), whereas the second one consists of models that scientists have extracted from collected, natural or synthetic data. Even if one can be confident on the first type of equations, the second one contains modeling errors. Moreover, this second type of equations remains too particular and often fails in describing new experimental results. The vast majority of existing models lack of generality, and therefore must be constantly adapted or enriched to describe new experimental findings. In this work we propose a new method, able to directly link data to computers in order to perform numerical simulations. These simulations will employ axiomatic, universal laws while minimizing the need of explicit, often phenomenological, models. This technique is based on the use of manifold learning methodologies, that allow to extract the relevant information from large experimental datasets.
Bio
Elías Cueto is Professor of Applied Mechanics and Bioengineering at the University of Zaragoza, where he remained after obtained his PhD. He has co-authored over 80 peer-reviewed articles, four books on numerical methods applied to Engineering. He has received the Juan Simo award by the SEMNI, the ESAFORM scientific prize by the European Association of Material Forming, the CETIM Foundation prize, and the Zienkiewicz award by ECCOMAS. He has been recently named president of the Spanish Association for Numerical Methods in Engineering.