Stiff systems of ordinary differential equations (ODEs) and sparse training data are common in scientific problems. This paper describes efficient, implicit, vectorized methods for integrating stiff systems of ordinary differential equations through time and calculating parameter gradients with the adjoint method. The main innovation is to vectorize the problem both over the number of independent times series and over a batch or "chunk" of sequential time steps, effectively vectorizing the assembly of the implicit system of ODEs. The block-bidiagonal structure of the linearized implicit system for the backward Euler method allows for further vectorization using parallel cyclic reduction (PCR). Vectorizing over both axes of the input data pr...
International audienceThis paper introduces a new class of numerical methods for the time integratio...
Measurement noise is an integral part while collecting data of a physical process. Thus, noise remov...
This paper introduces two new numerical methods for integration of stiff ordinary differential equat...
We introduce economical versions of standard implicit ODE solvers that are specifically tailored for...
Neural differential equations may be trained by backpropagating gradients via the adjoint method, wh...
In this paper, new integration methods for stiff ordinary differential equations (ODEs) are develope...
We propose a machine learning framework to accelerate numerical computations of time-dependent ODEs ...
Training Neural Ordinary Differential Equations (ODEs) is often computationally expensive. Indeed, c...
AbstractA natural approach for giving a positive answer to the need of faster ODE solvers consists i...
Neural ordinary differential equations (neural ODEs) have emerged as a novel network architecture th...
AbstractThe use of implicit methods for numerically solving stiff systems of differential equations ...
Ordinary differential equation (ODE) models are a key tool to understand complex mechanisms in syste...
The long runtime of high-fidelity partial differential equation (PDE) solvers makes them unsuitable ...
The dynamics of many systems are described by ordinary differential equations (ODE). Solving ODEs wi...
Embedding nonlinear dynamical systems into artificial neural networks is a powerful new formalism fo...
International audienceThis paper introduces a new class of numerical methods for the time integratio...
Measurement noise is an integral part while collecting data of a physical process. Thus, noise remov...
This paper introduces two new numerical methods for integration of stiff ordinary differential equat...
We introduce economical versions of standard implicit ODE solvers that are specifically tailored for...
Neural differential equations may be trained by backpropagating gradients via the adjoint method, wh...
In this paper, new integration methods for stiff ordinary differential equations (ODEs) are develope...
We propose a machine learning framework to accelerate numerical computations of time-dependent ODEs ...
Training Neural Ordinary Differential Equations (ODEs) is often computationally expensive. Indeed, c...
AbstractA natural approach for giving a positive answer to the need of faster ODE solvers consists i...
Neural ordinary differential equations (neural ODEs) have emerged as a novel network architecture th...
AbstractThe use of implicit methods for numerically solving stiff systems of differential equations ...
Ordinary differential equation (ODE) models are a key tool to understand complex mechanisms in syste...
The long runtime of high-fidelity partial differential equation (PDE) solvers makes them unsuitable ...
The dynamics of many systems are described by ordinary differential equations (ODE). Solving ODEs wi...
Embedding nonlinear dynamical systems into artificial neural networks is a powerful new formalism fo...
International audienceThis paper introduces a new class of numerical methods for the time integratio...
Measurement noise is an integral part while collecting data of a physical process. Thus, noise remov...
This paper introduces two new numerical methods for integration of stiff ordinary differential equat...
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