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Main Authors: Liu, Huihan, Zhang, Yu, Betala, Vaarij, Zhang, Evan, Liu, James, Ding, Crystal, Zhu, Yuke
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2410.22689
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author Liu, Huihan
Zhang, Yu
Betala, Vaarij
Zhang, Evan
Liu, James
Ding, Crystal
Zhu, Yuke
author_facet Liu, Huihan
Zhang, Yu
Betala, Vaarij
Zhang, Evan
Liu, James
Ding, Crystal
Zhu, Yuke
contents Recent advancements in large-scale multi-task robot learning offer the potential for deploying robot fleets in household and industrial settings, enabling them to perform diverse tasks across various environments. However, AI-enabled robots often face challenges with generalization and robustness when exposed to real-world variability and uncertainty. We introduce Sirius-Fleet, a multi-task interactive robot fleet learning framework to address these challenges. Sirius-Fleet monitors robot performance during deployment and involves humans to correct the robot's actions when necessary. We employ a visual world model to predict the outcomes of future actions and build anomaly predictors to predict whether they will likely result in anomalies. As the robot autonomy improves, the anomaly predictors automatically adapt their prediction criteria, leading to fewer requests for human intervention and gradually reducing human workload over time. Evaluations on large-scale benchmarks demonstrate Sirius-Fleet's effectiveness in improving multi-task policy performance and monitoring accuracy. We demonstrate Sirius-Fleet's performance in both RoboCasa in simulation and Mutex in the real world, two diverse, large-scale multi-task benchmarks. More information is available on the project website: https://ut-austin-rpl.github.io/sirius-fleet
format Preprint
id arxiv_https___arxiv_org_abs_2410_22689
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Multi-Task Interactive Robot Fleet Learning with Visual World Models
Liu, Huihan
Zhang, Yu
Betala, Vaarij
Zhang, Evan
Liu, James
Ding, Crystal
Zhu, Yuke
Robotics
Artificial Intelligence
Recent advancements in large-scale multi-task robot learning offer the potential for deploying robot fleets in household and industrial settings, enabling them to perform diverse tasks across various environments. However, AI-enabled robots often face challenges with generalization and robustness when exposed to real-world variability and uncertainty. We introduce Sirius-Fleet, a multi-task interactive robot fleet learning framework to address these challenges. Sirius-Fleet monitors robot performance during deployment and involves humans to correct the robot's actions when necessary. We employ a visual world model to predict the outcomes of future actions and build anomaly predictors to predict whether they will likely result in anomalies. As the robot autonomy improves, the anomaly predictors automatically adapt their prediction criteria, leading to fewer requests for human intervention and gradually reducing human workload over time. Evaluations on large-scale benchmarks demonstrate Sirius-Fleet's effectiveness in improving multi-task policy performance and monitoring accuracy. We demonstrate Sirius-Fleet's performance in both RoboCasa in simulation and Mutex in the real world, two diverse, large-scale multi-task benchmarks. More information is available on the project website: https://ut-austin-rpl.github.io/sirius-fleet
title Multi-Task Interactive Robot Fleet Learning with Visual World Models
topic Robotics
Artificial Intelligence
url https://arxiv.org/abs/2410.22689