Forecasting complex dynamical phenomena in settings where only partial knowledge of their dynamics is available is a prevalent problem across various scientific fields. While purely data-driven approaches are arguably insufficient in this context, standard physical modeling based approaches tend to be over-simplistic, inducing non-negligible errors. In this work, we introduce the APHYNITY framework, a principled approach for augmenting incomplete physical dynamics described by differential equations with deep data-driven models. It consists in decomposing the dynamics into two components: a physical component accounting for the dynamics for which we have some prior knowledge, and a data-driven component accounting for errors of the physical...
The modeling of natural processes relies on a physical description that prescribes the changes in th...
In this paper we present a deep learning method to predict the temporal evolution of dissipative dyn...
We explore training deep neural network models in conjunction with physical simulations via partial ...
International audienceForecasting complex dynamical phenomena in settings where only partial knowled...
Over the last decade, deep learning methods have achieved success in diverse domains, becoming one o...
When predicting complex systems one typically relies on differential equation which can often be inc...
The physical world around us is profoundly complex and for centuries we have sought to develop a dee...
The success of the current wave of artificial intelligence can be partly attributed to deep neural n...
In this paper, we propose a probabilistic physics-guided framework, termed Physics-guided Deep Marko...
Recent progress in machine learning has shown how to forecast and, to some extent, learn the dynamic...
Differential equations based on physical principals are used to represent complex dynamic systems in...
Data-driven approximations of ordinary differential equations offer a promising alternative to class...
Dynamical systems see widespread use in natural sciences like physics, biology, chemistry, as well a...
International audienceEffective inclusion of physics-based knowledge into deep neural network models...
The modeling of natural processes relies on a physical description that prescribes the changes in th...
In this paper we present a deep learning method to predict the temporal evolution of dissipative dyn...
We explore training deep neural network models in conjunction with physical simulations via partial ...
International audienceForecasting complex dynamical phenomena in settings where only partial knowled...
Over the last decade, deep learning methods have achieved success in diverse domains, becoming one o...
When predicting complex systems one typically relies on differential equation which can often be inc...
The physical world around us is profoundly complex and for centuries we have sought to develop a dee...
The success of the current wave of artificial intelligence can be partly attributed to deep neural n...
In this paper, we propose a probabilistic physics-guided framework, termed Physics-guided Deep Marko...
Recent progress in machine learning has shown how to forecast and, to some extent, learn the dynamic...
Differential equations based on physical principals are used to represent complex dynamic systems in...
Data-driven approximations of ordinary differential equations offer a promising alternative to class...
Dynamical systems see widespread use in natural sciences like physics, biology, chemistry, as well a...
International audienceEffective inclusion of physics-based knowledge into deep neural network models...
The modeling of natural processes relies on a physical description that prescribes the changes in th...
In this paper we present a deep learning method to predict the temporal evolution of dissipative dyn...
We explore training deep neural network models in conjunction with physical simulations via partial ...