In this paper, we address the adversarial training of neural ODEs from a robust control perspective. This is an alternative to the classical training via empirical risk minimization, and it is widely used to enforce reliable outcomes for input perturbations. Neural ODEs allow the interpretation of deep neural networks as discretizations of control systems, unlocking powerful tools from control theory for the development and the understanding of machine learning. In this specific case, we formulate the adversarial training with perturbed data as a minimax optimal control problem, for which we derive first order optimality conditions in the form of Pontryagin's Maximum Principle. We provide a novel interpretation of robust training leading to...
Deep Convolution Neural Networks (CNNs) can easily be fooled by subtle, imperceptible changes to the...
Neural networks are vulnerable to adversarial attacks: adding well-crafted, imperceptible perturbati...
Hamiltonians can generate Artificial Neural Dynamical systems dependent on time. Classical methods f...
Optimal control problems naturally arise in many scientific applications where one wishes to steer a...
We propose a neural network approach for solving high-dimensional optimal control problems. In parti...
This paper introduces a reinforcement learning-based tracking control approach for a class of nonlin...
We consider recent work of Haber and Ruthotto 2017 and Chang et al. 2018, where deep learning neural...
We consider recent work of Haber and Ruthotto 2017 and Chang et al. 2018, where deep learning neural...
This paper considers the problem of controlling a dynamical system when the state cannot be directly...
In this paper we propose a Deep Learning architecture to approximate diffeomorphisms diffeotopic to ...
Recent research shows that supervised learning can be an effective tool for designing near-optimal f...
Every optimization problem shares the common objective of finding a minima/maxima, but its applicati...
Neural networks are vulnerable to adversarial attacks: adding well-crafted, imperceptible perturbati...
We briefly review recent work where deep learning neural networks have been interpreted as discretis...
We study the optimal control in a long time horizon of neural ordinary differential equations which ...
Deep Convolution Neural Networks (CNNs) can easily be fooled by subtle, imperceptible changes to the...
Neural networks are vulnerable to adversarial attacks: adding well-crafted, imperceptible perturbati...
Hamiltonians can generate Artificial Neural Dynamical systems dependent on time. Classical methods f...
Optimal control problems naturally arise in many scientific applications where one wishes to steer a...
We propose a neural network approach for solving high-dimensional optimal control problems. In parti...
This paper introduces a reinforcement learning-based tracking control approach for a class of nonlin...
We consider recent work of Haber and Ruthotto 2017 and Chang et al. 2018, where deep learning neural...
We consider recent work of Haber and Ruthotto 2017 and Chang et al. 2018, where deep learning neural...
This paper considers the problem of controlling a dynamical system when the state cannot be directly...
In this paper we propose a Deep Learning architecture to approximate diffeomorphisms diffeotopic to ...
Recent research shows that supervised learning can be an effective tool for designing near-optimal f...
Every optimization problem shares the common objective of finding a minima/maxima, but its applicati...
Neural networks are vulnerable to adversarial attacks: adding well-crafted, imperceptible perturbati...
We briefly review recent work where deep learning neural networks have been interpreted as discretis...
We study the optimal control in a long time horizon of neural ordinary differential equations which ...
Deep Convolution Neural Networks (CNNs) can easily be fooled by subtle, imperceptible changes to the...
Neural networks are vulnerable to adversarial attacks: adding well-crafted, imperceptible perturbati...
Hamiltonians can generate Artificial Neural Dynamical systems dependent on time. Classical methods f...