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1. Deep Reinforcement Learning for Procedural Content Generation of 3D Virtual Environments

   https://doi.org/10.1115/1.4046293  

   López, Christian E.; Cunningham, James; Ashour, Omar; Tucker, Conrad S. (October 2020, Journal of Computing and Information Science in Engineering)

   Abstract This work presents a deep reinforcement learning (DRL) approach for procedural content generation (PCG) to automatically generate three-dimensional (3D) virtual environments that users can interact with. The primary objective of PCG methods is to algorithmically generate new content in order to improve user experience. Researchers have started exploring the use of machine learning (ML) methods to generate content. However, these approaches frequently implement supervised ML algorithms that require initial datasets to train their generative models. In contrast, RL algorithms do not require training data to be collected a priori since they take advantage of simulation to train their models. Considering the advantages of RL algorithms, this work presents a method that generates new 3D virtual environments by training an RL agent using a 3D simulation platform. This work extends the authors’ previous work and presents the results of a case study that supports the capability of the proposed method to generate new 3D virtual environments. The ability to automatically generate new content has the potential to maintain users’ engagement in a wide variety of applications such as virtual reality applications for education and training, and engineering conceptual design. 

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2. Skill Discovery for Exploration and Planning using Deep Skill Graphs

   Bagaria, A; Senthil, J; Konidaris, G (July 2021, Proceedings of the Thirty-Eighth International Conference on Machine Learning)

   null (Ed.)

   We introduce a new skill-discovery algorithm that builds a discrete graph representation of large continuous MDPs, where nodes correspond to skill subgoals and the edges to skill policies. The agent constructs this graph during an unsupervised training phase where it interleaves discovering skills and planning using them to gain coverage over ever-increasing portions of the state-space. Given a novel goal at test time, the agent plans with the acquired skill graph to reach a nearby state, then switches to learning to reach the goal. We show that the resulting algorithm, Deep Skill Graphs, outperforms both flat and existing hierarchical reinforcement learning methods on four difficult continuous control tasks. 

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3. Skill Discovery for Exploration and Planning using Deep Skill Graphs

   Bagaria, A; Senthil, J.; Konidaris, G.D. (July 2021, Proceedings of the Thirty-Eighth International Conference on Machine Learning)

   We introduce a new skill-discovery algorithm that builds a discrete graph representation of large continuous MDPs, where nodes correspond to skill subgoals and the edges to skill policies. The agent constructs this graph during an unsupervised training phase where it interleaves discovering skills and planning using them to gain coverage over ever-increasing portions of the state-space. Given a novel goal at test time, the agent plans with the acquired skill graph to reach a nearby state, then switches to learning to reach the goal. We show that the resulting algorithm, Deep Skill Graphs, outperforms both flat and existing hierarchical reinforcement learning methods on four difficult continuous control tasks. 

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4. Skill Preferences: Learning to Extract and Execute Robotic Skills from Human Feedback

   Wang, Xiaofei; Lee, Kimin; Hakhamaneshi, Kourosh; Abbeel, Pieter: Laskin (November 2021, Conference on Robot Learning)

   null (Ed.)

   A promising approach to solving challenging long-horizon tasks has been to extract behavior priors (skills) by fitting generative models to large offline datasets of demonstrations. However, such generative models inherit the biases of the underlying data and result in poor and unusable skills when trained on imperfect demonstration data. To better align skill extraction with human intent we present Skill Preferences (SkiP), an algorithm that learns a model over human preferences and uses it to extract human-aligned skills from offline data. After extracting human-preferred skills, SkiP also utilizes human feedback to solve downstream tasks with RL. We show that SkiP enables a simulated kitchen robot to solve complex multi-step manipulation tasks and substantially outperforms prior leading RL algorithms with human preferences as well as leading skill extraction algorithms without human preferences. 

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5. Search-Based Task Planning with Learned Skill Effect Models for Lifelong Robotic Manipulation

   https://doi.org/10.1109/ICRA46639.2022.9811575  

   Liang, Jacky; Sharma, Mohit; LaGrassa, Alex; Vats, Shivam; Saxena, Saumya; Kroemer, Oliver (May 2022, International Conference on Robotics and Automation (ICRA))

   Robots deployed in many real-world settings need to be able to acquire new skills and solve new tasks over time. Prior works on planning with skills often make assumptions on the structure of skills and tasks, such as subgoal skills, shared skill implementations, or task-specific plan skeletons, which limit adaptation to new skills and tasks. By contrast, we propose doing task planning by jointly searching in the space of parameterized skills using high-level skill effect models learned in simulation. We use an iterative training procedure to efficiently generate relevant data to train such models. Our approach allows flexible skill parameterizations and task specifications to facilitate lifelong learning in general-purpose domains. Experiments demonstrate the ability of our planner to integrate new skills in a lifelong manner, finding new task strategies with lower costs in both train and test tasks. We additionally show that our method can transfer to the real world without further fine-tuning. 

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