We develop inductive biases for the machine learning of complex physical systems based on the port-Hamiltonian formalism. To satisfy by construction the principles of thermodynamics in the learned physics (conservation of energy, non-negative entropy production), we modify accordingly the port-Hamiltonian formalism so as to achieve a port-metriplectic one. 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. Predictions can be done, however, at the scale of the complete system. Examples are shown on the performance of the proposed technique
In this article we study the possibilities of recovering the structure of port-Hamiltonian systems s...
We present a machine learning based approach to address the study of transport processes, ubiquitous...
Recent advancements in deep learning for physics have focused on discovering shared representations ...
We develop inductive biases for the machine learning of complex physical systems based on the port-H...
We develop a method to learn physical systems from data that employs feedforward neural networks and...
The physical world around us is profoundly complex and for centuries we have sought to develop a dee...
Despite the immense success of neural networks in modeling system dynamics from data, they often rem...
Hybrid machine learning based on Hamiltonian formulations has recently been successfully demonstrate...
We present a method for the data-driven learning of physical phenomena whose evolution in time depen...
Thermodynamics could be seen as an expression of physics at a high epistemic level. As such, its pot...
Abstract Transfer learning refers to the use of knowledge gained while solving a mach...
A physical process is a sustained phenomenon marked by gradual changes through a series of states oc...
It has been successfully demonstrated that synchronisation of physical prior, like conservation laws...
Hybrid machine learning based on Hamiltonian formulations has recently been successfully demonstrate...
Thermodynamics could be seen as an expression of physics at a high epistemic level. As such, its pot...
In this article we study the possibilities of recovering the structure of port-Hamiltonian systems s...
We present a machine learning based approach to address the study of transport processes, ubiquitous...
Recent advancements in deep learning for physics have focused on discovering shared representations ...
We develop inductive biases for the machine learning of complex physical systems based on the port-H...
We develop a method to learn physical systems from data that employs feedforward neural networks and...
The physical world around us is profoundly complex and for centuries we have sought to develop a dee...
Despite the immense success of neural networks in modeling system dynamics from data, they often rem...
Hybrid machine learning based on Hamiltonian formulations has recently been successfully demonstrate...
We present a method for the data-driven learning of physical phenomena whose evolution in time depen...
Thermodynamics could be seen as an expression of physics at a high epistemic level. As such, its pot...
Abstract Transfer learning refers to the use of knowledge gained while solving a mach...
A physical process is a sustained phenomenon marked by gradual changes through a series of states oc...
It has been successfully demonstrated that synchronisation of physical prior, like conservation laws...
Hybrid machine learning based on Hamiltonian formulations has recently been successfully demonstrate...
Thermodynamics could be seen as an expression of physics at a high epistemic level. As such, its pot...
In this article we study the possibilities of recovering the structure of port-Hamiltonian systems s...
We present a machine learning based approach to address the study of transport processes, ubiquitous...
Recent advancements in deep learning for physics have focused on discovering shared representations ...