[[{“value”:”
Reinforcement learning (RL) comprises a wide range of algorithms, typically divided into two main groups: model-based (MB) and model-free (MF) methods. MB algorithms rely on predictive models of environment feedback, termed world models, which simulate real-world dynamics. These models facilitate policy derivation through action exploration or policy optimization. Despite their potential, MB methods often need help with modeling inaccuracies, potentially leading to suboptimal performance compared to MF techniques.
A significant challenge in MB RL lies in minimizing world modeling inaccuracies. Traditional world models often suffer from limitations in their one-step dynamics, predicting the subsequent state and reward solely based on the current state and action. Researchers propose a novel approach called the Diffusion World Model (DWM) to address this limitation.
Unlike conventional models, DWM is a diffusion probabilistic model specifically tailored for predicting long-horizon outcomes. By simultaneously indicating multi-step future states and rewards without recursive querying, DWM eliminates the source of error accumulation.
DWM is trained using the available dataset, and policies are subsequently trained using synthesized data generated by DWM through an actor-critic approach. To enhance performance further, researchers introduced diffusion model value expansion (Diffusion-MVE) to simulate returns based on future trajectories generated by DWM. This method effectively utilizes generative modeling to facilitate offline Q-learning with synthetic data.
The effectiveness of their proposed framework is demonstrated through empirical evaluation, specifically in locomotion tasks from the D4RL benchmark. Comparing diffusion-based world models with traditional one-step models reveals notable performance improvements.
The diffusion world model achieves a remarkable 44% enhancement over one-step models across tasks in continuous action and observation spaces. Moreover, the framework’s ability to bridge the gap between MB and MF algorithms is underscored, with the method achieving state-of-the-art performance in offline RL, highlighting its potential to advance the field of reinforcement learning.
Furthermore, recent advancements in offline RL methodologies have primarily concentrated on MF algorithms, with limited attention paid to reconciling the disparities between MB and MF approaches. However, their framework tackles this gap by harnessing the strengths of both MB and MF paradigms.
By integrating the Diffusion World Model into the offline RL framework, one can achieve state-of-the-art performance, surmounting the limitations of traditional one-step world models. This underscores the significance of sequence modeling techniques in decision-making problems and the potential for hybrid approaches amalgamating the advantages of both MB and MF methods.
Check out the Paper. All credit for this research goes to the researchers of this project. Also, don’t forget to follow us on Twitter and Google News. Join our 37k+ ML SubReddit, 41k+ Facebook Community, Discord Channel, and LinkedIn Group.
If you like our work, you will love our newsletter..
Don’t Forget to join our Telegram Channel
The post This AI Paper Introduces the Diffusion World Model (DWM): A General Framework for Leveraging Diffusion Models as World Models in the Context of Offline Reinforcement learning appeared first on MarkTechPost.
“}]] [[{“value”:”Reinforcement learning (RL) comprises a wide range of algorithms, typically divided into two main groups: model-based (MB) and model-free (MF) methods. MB algorithms rely on predictive models of environment feedback, termed world models, which simulate real-world dynamics. These models facilitate policy derivation through action exploration or policy optimization. Despite their potential, MB methods often need
The post This AI Paper Introduces the Diffusion World Model (DWM): A General Framework for Leveraging Diffusion Models as World Models in the Context of Offline Reinforcement learning appeared first on MarkTechPost.”}]] Read More AI Shorts, Applications, Artificial Intelligence, Editors Pick, Machine Learning, Staff, Tech News, Technology, Uncategorized