Despite the recent success of deep reinforcement learning (RL), domain adaptation remains an open problem. Although the generalization ability of RL agents is critical for the real-world applicability of Deep RL, zero-shot policy transfer is still a challenging problem since even minor visual changes could make the trained agent completely fail in the new task. To address this issue, we propose a two-stage RL agent that first learns a latent unified state representation (LUSR) which is consistent across multiple domains in the first stage, and then do RL training in one source domain based on LUSR in the second stage. The cross-domain consistency of LUSR allows the policy acquired from the source domain to generalize to other target domains...
Realistic domains for learning possess regularities that make it possible to generalize experience a...
Skill-based reinforcement learning (RL) has emerged as a promising strategy to leverage prior knowle...
In the quest for efficient and robust learning methods, combining unsupervised state representation ...
Deep Reinforcement learning is a powerful machine learning paradigm that has had significant success...
© 2018 AI Access Foundation. All rights reserved. In this paper, we explore the utilization of natur...
A long standing goal of robotics research is to create algorithms that can automatically learn compl...
Typical reinforcement learning (RL) agents learn to complete tasks specified by reward functions tai...
In control, the objective is to find a mapping from states to actions that steer a system to a desir...
Reinforcement learning has long been advertised as the one with the capability to intelligently mimi...
In the past few years, deep reinforcement learning (RL) has shown great potential in learning action...
Deep Reinforcement Learning (RL) is a promising technique towards constructing intelligent agents, b...
Reinforcement Learning has achieved noticeable success in many fields, such as video game playing, c...
Reinforcement learning algorithms have proven to be capable of solving complicated robotics tasks in...
Applying deep reinforcement learning to physical systems, as opposed to learning in simulation, pres...
Agents, physical and virtual entities that interact with theirenvironment, are becoming increasingly...
Realistic domains for learning possess regularities that make it possible to generalize experience a...
Skill-based reinforcement learning (RL) has emerged as a promising strategy to leverage prior knowle...
In the quest for efficient and robust learning methods, combining unsupervised state representation ...
Deep Reinforcement learning is a powerful machine learning paradigm that has had significant success...
© 2018 AI Access Foundation. All rights reserved. In this paper, we explore the utilization of natur...
A long standing goal of robotics research is to create algorithms that can automatically learn compl...
Typical reinforcement learning (RL) agents learn to complete tasks specified by reward functions tai...
In control, the objective is to find a mapping from states to actions that steer a system to a desir...
Reinforcement learning has long been advertised as the one with the capability to intelligently mimi...
In the past few years, deep reinforcement learning (RL) has shown great potential in learning action...
Deep Reinforcement Learning (RL) is a promising technique towards constructing intelligent agents, b...
Reinforcement Learning has achieved noticeable success in many fields, such as video game playing, c...
Reinforcement learning algorithms have proven to be capable of solving complicated robotics tasks in...
Applying deep reinforcement learning to physical systems, as opposed to learning in simulation, pres...
Agents, physical and virtual entities that interact with theirenvironment, are becoming increasingly...
Realistic domains for learning possess regularities that make it possible to generalize experience a...
Skill-based reinforcement learning (RL) has emerged as a promising strategy to leverage prior knowle...
In the quest for efficient and robust learning methods, combining unsupervised state representation ...