Long-horizon manipulation tasks such as stacking represent a longstanding challenge in the field of robotic manipulation, particularly when using reinforcement learning (RL) methods which often struggle to learn the correct sequence of actions for achieving these complex goals. To learn this sequence, symbolic planning methods offer a good solution based on high-level reasoning, however, planners often fall short in addressing the low-level control specificity needed for precise execution. This paper introduces a novel framework that integrates symbolic planning with hierarchical RL through the cooperation of high-level operators and low-level policies. Our contribution integrates planning operators (e.g. preconditions and effects) as part ...
Deep reinforcement learning has shown its effectiveness in various applications, providing a promisi...
Search based planners such as A* and Dijkstra\u27s algorithm are proven methods for guiding today\u2...
Task and motion planning problems in robotics combine symbolic planning over discrete task variables...
Multistep tasks, such as block stacking or parts (dis)assembly, are complex for autonomous robotic m...
In this paper we present a hybrid system combining techniques from symbolic planning and reinforceme...
We present HiDe, a novel hierarchical reinforcement learning architecture that successfully solves l...
An obstacle that prevents the wide adoption of (deep) reinforcement learning (RL) in control systems...
Two common approaches to sequential decision-making are AI planning (AIP) and reinforcement learning...
Deep reinforcement learning (DRL) has gained great success by learning directly from high-dimensiona...
We consider the problem of how to plan efficiently in low-level, continuous state spaces with tempor...
Deep reinforcement learning (DRL) has gained great success by learning directly from high-dimensiona...
Solutions to real world robotic tasks often require complex behaviors in high dimensional continuou...
An effective approach to solving long-horizon tasks in robotics domains with continuous state and ac...
Reinforcement learning (RL) is an area of Machine Learning (ML) concerned with learning how a softwa...
One of the main challenges in Artificial Intelligence is the problem of abstracting high-level model...
Deep reinforcement learning has shown its effectiveness in various applications, providing a promisi...
Search based planners such as A* and Dijkstra\u27s algorithm are proven methods for guiding today\u2...
Task and motion planning problems in robotics combine symbolic planning over discrete task variables...
Multistep tasks, such as block stacking or parts (dis)assembly, are complex for autonomous robotic m...
In this paper we present a hybrid system combining techniques from symbolic planning and reinforceme...
We present HiDe, a novel hierarchical reinforcement learning architecture that successfully solves l...
An obstacle that prevents the wide adoption of (deep) reinforcement learning (RL) in control systems...
Two common approaches to sequential decision-making are AI planning (AIP) and reinforcement learning...
Deep reinforcement learning (DRL) has gained great success by learning directly from high-dimensiona...
We consider the problem of how to plan efficiently in low-level, continuous state spaces with tempor...
Deep reinforcement learning (DRL) has gained great success by learning directly from high-dimensiona...
Solutions to real world robotic tasks often require complex behaviors in high dimensional continuou...
An effective approach to solving long-horizon tasks in robotics domains with continuous state and ac...
Reinforcement learning (RL) is an area of Machine Learning (ML) concerned with learning how a softwa...
One of the main challenges in Artificial Intelligence is the problem of abstracting high-level model...
Deep reinforcement learning has shown its effectiveness in various applications, providing a promisi...
Search based planners such as A* and Dijkstra\u27s algorithm are proven methods for guiding today\u2...
Task and motion planning problems in robotics combine symbolic planning over discrete task variables...