Robotic World Model: A Neural Network Simulator for Robust Policy Optimization in Robotics
Abstract
Learning robust and generalizable world models is crucial for enabling efficient and scalable robotic control in real-world environments. In this work, we introduce a novel framework for learning world models that accurately capture complex, partially observable, and stochastic dynamics. The proposed method employs a dual-autoregressive mechanism and self-supervised training to achieve reliable long-horizon predictions without relying on domain-specific inductive biases, ensuring adaptability across diverse robotic tasks. We further propose a policy optimization framework that leverages world models for efficient training in imagined environments and seamless deployment in real-world systems. This work advances model-based reinforcement learning by addressing the challenges of long-horizon prediction, error accumulation, and sim-to-real transfer. By providing a scalable and robust framework, the introduced methods pave the way for adaptive and efficient robotic systems in real-world applications.
Cite
@article{arxiv.2501.10100,
title = {Robotic World Model: A Neural Network Simulator for Robust Policy Optimization in Robotics},
author = {Chenhao Li and Andreas Krause and Marco Hutter},
journal= {arXiv preprint arXiv:2501.10100},
year = {2025}
}