DyNODE: Neural Ordinary Differential Equations for Dynamics Modeling in Continuous Control
Alvarez, Victor M. Martinez, Roşca, Rareş, Fălcuţescu, Cristian G.
We present a novel approach (DyNODE) that captures the underlying dynamics of a system by incorporating control in a neural ordinary differential equation framework. We conduct a systematic evaluation and comparison of our method and standard neural network architectures for dynamics modeling. Our results indicate that a simple DyNODE architecture when combined with an actor-critic reinforcement learning (RL) algorithm that uses model predictions to improve the critic's target values, outperforms canonical neural networks, both in sample efficiency and predictive performance across a diverse range of continuous tasks that are frequently used to benchmark RL algorithms. This approach provides a new avenue for the development of models that are more suited to learn the evolution of dynamical systems, particularly useful in the context of model-based reinforcement learning. To assist related work, we have made code available at https://github.com/vmartinezalvarez/DyNODE .
Sep-9-2020
- Country:
- Europe > Romania
- Nord-Vest Development Region > Cluj County > Cluj-Napoca (0.04)
- Asia > Middle East
- Jordan (0.04)
- Europe > Romania
- Genre:
- Research Report (1.00)
- Technology: