Puze Liu scite author profile

Motion planning is a mature area of research in robotics with many well-established methods based on optimization or sampling the state space, suitable for solving kinematic motion planning. However, when dynamic motions under constraints are needed and computation time is limited, fast kinodynamic planning on the constraint manifold is indispensable. In recent years, learning-based solutions have become alternatives to classical approaches, but they still lack comprehensive handling of complex constraints, such as planning on a lowerdimensional manifold of the task space while considering the robot's dynamics. This paper introduces a novel learning-toplan framework that exploits the concept of constraint manifold, including dynamics, and neural planning methods. Our approach generates plans satisfying an arbitrary set of constraints and computes them in a short constant time, namely the inference time of a neural network. This allows the robot to plan and replan reactively, making our approach suitable for dynamic environments. We validate our approach on two simulated tasks and in a demanding real-world scenario, where we use a Kuka LBR Iiwa 14 robotic arm to perform the hitting movement in robotic Air Hockey.

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Efficient and Reactive Planning for High Speed Robot Air Hockey

Liu¹,

Tateo²,

Bou-Ammar³

et al. 2021

Preprint

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Highly dynamic robotic tasks require high-speed and reactive robots. These tasks are particularly challenging due to the physical constraints, hardware limitations, and the high uncertainty of dynamics and sensor measures. To face these issues, it's crucial to design robotics agents that generate precise and fast trajectories and react immediately to environmental changes. Air hockey is an example of this kind of task. Due to the environment's characteristics, it is possible to formalize the problem and derive clean mathematical solutions. For these reasons, this environment is perfect for pushing to the limit the performance of currently available general-purpose robotic manipulators. Using two Kuka Iiwa 14, we show how to design a policy for general-purpose robotic manipulators for the air hockey game. We demonstrate that a real robot arm can perform fast-hitting movements and that the two robots can play against each other on a medium-size air hockey table in simulation.

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Puze Liu

Composable Energy Policies for Reactive Motion Generation and Reinforcement Learning

Efficient and Reactive Planning for High Speed Robot Air Hockey

Regularized Deep Signed Distance Fields for Reactive Motion Generation

Fast Kinodynamic Planning on the Constraint Manifold with Deep Neural Networks

Efficient and Reactive Planning for High Speed Robot Air Hockey

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