Robotic navigation in environments shared with other robots or humans remains challenging because the intentions of the surrounding agents are not directly observable and the environment conditions are continuously changing. Local trajectory optimization methods, such as model predictive control (MPC), can deal with those changes but require global guidance, which is not trivial to obtain in crowded scenarios. This paper proposes to learn, via deep Reinforcement Learning (RL), an interaction-aware policy that provides long-term guidance to the local planner. In particular, in simulations with cooperative and non-cooperative agents, we train a deep network to recommend a subgoal for the MPC planner. The recommended subgoal is expected to hel...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Aeronautics and Astronautics, 2...
Since an individual approach can hardly navigate robots through complex environments, we present a n...
Search missions require motion planning and navigation methods for information gathering that contin...
Autonomous robots will profoundly impact our society, making our roads safer, reducing labor costs a...
Mobile robots that operate in human environments require the ability to safely navigate among humans...
© 2013 IEEE. Collision avoidance algorithms are essential for safe and efficient robot operation amo...
© 2018 IEEE. Robots that navigate among pedestrians use collision avoidance algorithms to enable saf...
This paper presents a data-driven decentralized trajectory optimization approach for multi-robot mot...
Motion planning for autonomous robots in tight, interaction-rich, and mixed human-robot environments...
Multi-robot motion planning without a central coordinator usually relies on the sharing of planned t...
In this paper we tackle motion planning in industrial human-robot cooperative scenarios modeled as a...
An approach to motion planning for human robot cooperation based on Deep Reinforcement Learning in s...
Solving obstacle-clustered robotic navigation tasks via model-free reinforcement learning (RL) is ch...
Autonomous navigation in dense traffic scenarios remains challenging for autonomous vehicles (AVs) b...
Socially compliant robot navigation in pedestrian environments remains challenging owing to uncertai...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Aeronautics and Astronautics, 2...
Since an individual approach can hardly navigate robots through complex environments, we present a n...
Search missions require motion planning and navigation methods for information gathering that contin...
Autonomous robots will profoundly impact our society, making our roads safer, reducing labor costs a...
Mobile robots that operate in human environments require the ability to safely navigate among humans...
© 2013 IEEE. Collision avoidance algorithms are essential for safe and efficient robot operation amo...
© 2018 IEEE. Robots that navigate among pedestrians use collision avoidance algorithms to enable saf...
This paper presents a data-driven decentralized trajectory optimization approach for multi-robot mot...
Motion planning for autonomous robots in tight, interaction-rich, and mixed human-robot environments...
Multi-robot motion planning without a central coordinator usually relies on the sharing of planned t...
In this paper we tackle motion planning in industrial human-robot cooperative scenarios modeled as a...
An approach to motion planning for human robot cooperation based on Deep Reinforcement Learning in s...
Solving obstacle-clustered robotic navigation tasks via model-free reinforcement learning (RL) is ch...
Autonomous navigation in dense traffic scenarios remains challenging for autonomous vehicles (AVs) b...
Socially compliant robot navigation in pedestrian environments remains challenging owing to uncertai...
Thesis: Ph. D., Massachusetts Institute of Technology, Department of Aeronautics and Astronautics, 2...
Since an individual approach can hardly navigate robots through complex environments, we present a n...
Search missions require motion planning and navigation methods for information gathering that contin...