Search Results for author:
Found 8 papers, 3 papers with code
Thermodynamics of learning physical phenomena
Thermodynamics could be seen as an expression of physics at a high epistemic level.
A Thermodynamics-informed Active Learning Approach to Perception and Reasoning about Fluids
Learning and reasoning about physical phenomena is still a challenge in robotics development, and computational sciences play a capital role in the search for accurate methods able to provide explanations for past events and rigorous forecasts of future situations.
Monitoring weeder robots and anticipating their functioning by using advanced topological data analysis
The present paper aims at analyzing the topological content of the complex trajectories that weeder-autonomous robots follow in operation.
Physics perception in sloshing scenes with guaranteed thermodynamic consistency
Physics perception very often faces the problem that only limited data or partial measurements on the scene are available.
Learning stable reduced-order models for hybrid twins
The concept of Hybrid Twin (HT) has recently received a growing interest thanks to the availability of powerful machine learning techniques.
MORPH-DSLAM: Model Order Reduction for PHysics-based Deformable SLAM
We propose a new methodology to estimate the 3D displacement field of deformable objects from video sequences using standard monocular cameras.
Deep learning of thermodynamics-aware reduced-order models from data
We present an algorithm to learn the relevant latent variables of a large-scale discretized physical system and predict its time evolution using thermodynamically-consistent deep neural networks.
Structure-preserving neural networks
The method employs a minimum amount of data by enforcing the metriplectic structure of dissipative Hamiltonian systems in the form of the so-called General Equation for the Non-Equilibrium Reversible-Irreversible Coupling, GENERIC [M. Grmela and H. C Oettinger (1997).
