Search Results for author: Francisco Chinesta

Found 12 papers, 6 papers with code

Structure-preserving neural networks

1 code implementation9 Apr 2020 Quercus Hernández, Alberto Badias, David Gonzalez, Francisco Chinesta, Elias Cueto

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).

Deep learning of thermodynamics-aware reduced-order models from data

1 code implementation3 Jul 2020 Quercus Hernandez, Alberto Badias, David Gonzalez, Francisco Chinesta, Elias Cueto

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.

Total Energy

MORPH-DSLAM: Model Order Reduction for PHysics-based Deformable SLAM

no code implementations1 Sep 2020 Alberto Badias, Iciar Alfaro, David Gonzalez, Francisco Chinesta, Elias Cueto

We propose a new methodology to estimate the 3D displacement field of deformable objects from video sequences using standard monocular cameras.

MORPH

Learning stable reduced-order models for hybrid twins

no code implementations7 Jun 2021 Abel Sancarlos, Morgan Cameron, Jean-Marc Le Peuvedic, Juliette Groulier, Jean-Louis Duval, Elias Cueto, Francisco Chinesta

The concept of Hybrid Twin (HT) has recently received a growing interest thanks to the availability of powerful machine learning techniques.

Physics perception in sloshing scenes with guaranteed thermodynamic consistency

no code implementations24 Jun 2021 Beatriz Moya, Alberto Badias, David Gonzalez, Francisco Chinesta, Elias Cueto

Physics perception very often faces the problem that only limited data or partial measurements on the scene are available.

Thermodynamics-informed graph neural networks

1 code implementation3 Mar 2022 Quercus Hernández, Alberto Badías, Francisco Chinesta, Elías Cueto

In this paper we present a deep learning method to predict the temporal evolution of dissipative dynamic systems.

A Thermodynamics-informed Active Learning Approach to Perception and Reasoning about Fluids

1 code implementation11 Mar 2022 Beatriz Moya, Alberto Badias, David Gonzalez, Francisco Chinesta, Elias Cueto

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.

Active Learning

Thermodynamics of learning physical phenomena

no code implementations26 Jul 2022 Elias Cueto, Francisco Chinesta

Thermodynamics could be seen as an expression of physics at a high epistemic level.

Inductive Bias

Thermodynamics-informed neural networks for physically realistic mixed reality

1 code implementation24 Oct 2022 Quercus Hernández, Alberto Badías, Francisco Chinesta, Elías Cueto

The imminent impact of immersive technologies in society urges for active research in real-time and interactive physics simulation for virtual worlds to be realistic.

Mixed Reality

Port-metriplectic neural networks: thermodynamics-informed machine learning of complex physical systems

1 code implementation3 Nov 2022 Quercus Hernández, Alberto Badías, Francisco Chinesta, Elías Cueto

We show that the constructed networks are able to learn the physics of complex systems by parts, thus alleviating the burden associated to the experimental characterization and posterior learning process of this kind of systems.

Thermodynamics-informed super-resolution of scarce temporal dynamics data

no code implementations27 Feb 2024 Carlos Bermejo-Barbanoj, Beatriz Moya, Alberto Badías, Francisco Chinesta, Elías Cueto

Then, a second neural network is trained to learn the physical structure of the latent variables and predict their temporal evolution.

Super-Resolution

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