Jingxi Xu scite author profile

Jingxi Xu

5Publications

85Citation Statements Received

63Citation Statements Given

How they've been cited

How they cite others

124

Affiliations

Columbia University, Chinese University of Hong Kong, Tencent (China)

Publications

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Dynamic Grasping with Reachability and Motion Awareness

Akinola

Song

et al. 2021

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Grasping in dynamic environments presents a unique set of challenges. A stable and reachable grasp can become unreachable and unstable as the target object moves, motion planning needs to be adaptive and in real time, the delay in computation makes prediction necessary. In this paper, we present a dynamic grasping framework that is reachabilityaware and motion-aware. Specifically, we model the reachability space of the robot using a signed distance field which enables us to quickly screen unreachable grasps. Also, we train a neural network to predict the grasp quality conditioned on the current motion of the target. Using these as ranking functions, we quickly filter a large grasp database to a few grasps in real time. In addition, we present a seeding approach for arm motion generation that utilizes solution from previous time step. This quickly generates a new arm trajectory that is close to the previous plan and prevents fluctuation. We implement a recurrent neural network (RNN) for modelling and predicting the object motion. Our extensive experiments demonstrate the importance of each of these components and we validate our pipeline on a real robot.

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Accelerated Robot Learning via Human Brain Signals

Akinola

Wang

Shi

et al. 2020

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TANDEM: Learning Joint Exploration and Decision Making With Tactile Sensors

Song

Ciocarlie

2022

IEEE Robot. Autom. Lett.

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Learning Your Way Without Map or Compass: Panoramic Target Driven Visual Navigation

Watkins-Valls

Waytowich

et al. 2020

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Accelerated Robot Learning via Human Brain Signals

Akinola¹,

Wang²,

Shi³

et al. 2019

Preprint

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In reinforcement learning (RL), sparse rewards are a natural way to specify the task to be learned. However, most RL algorithms struggle to learn in this setting since the learning signal is mostly zeros. In contrast, humans are good at assessing and predicting the future consequences of actions and can serve as good reward/policy shapers to accelerate the robot learning process. Previous works have shown that the human brain generates an error-related signal, measurable using electroencephelography (EEG), when the human perceives the task being done erroneously. In this work, we propose a method that uses evaluative feedback obtained from human brain signals measured via scalp EEG to accelerate RL for robotic agents in sparse reward settings. As the robot learns the task, the EEG of a human observer watching the robot attempts is recorded and decoded into noisy error feedback signal. From this feedback, we use supervised learning to obtain a policy that subsequently augments the behavior policy and guides exploration in the early stages of RL. This bootstraps the RL learning process to enable learning from sparse reward. Using a robotic navigation task as a test bed, we show that our method achieves a stable obstacle-avoidance policy with high success rate, outperforming learning from sparse rewards only that struggles to achieve obstacle avoidance behavior or fails to advance to the goal.

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Jingxi Xu

Dynamic Grasping with Reachability and Motion Awareness

Accelerated Robot Learning via Human Brain Signals

TANDEM: Learning Joint Exploration and Decision Making With Tactile Sensors

Learning Your Way Without Map or Compass: Panoramic Target Driven Visual Navigation

Accelerated Robot Learning via Human Brain Signals

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