2021
DOI: 10.1007/s10846-021-01312-6
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Endowing Robots with Longer-term Autonomy by Recovering from External Disturbances in Manipulation Through Grounded Anomaly Classification and Recovery Policies

Abstract: Robots are poised to interact with humans in unstructured environments. Despite increasingly robust control algorithms, failure modes arise whenever the underlying dynamics are poorly modeled, especially in unstructured environments. We contribute a set of recovery policies to deal with anomalies produced by external disturbances. The recoveries work when various different types of anomalies are triggered any number of times at any point in the task, including during already running recoveries. Our recovery cr… Show more

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Cited by 5 publications
(1 citation statement)
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References 52 publications
(115 reference statements)
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“…In another work [32], a probabilistic method is proposed to predict failure cases for humanoid robots in hazardous environments by associating risks with related actions. Another study uses Hierarchical Dirichlet Process HMMs [33] to identify and classify anomalies that arise during collaborative kitting tasks. Yet another work presents a tensor voting-based method combined with support vector machines (SVMs) for classifying surface anomalies using 3D point cloud data [34].…”
Section: Literature Reviewmentioning
confidence: 99%
“…In another work [32], a probabilistic method is proposed to predict failure cases for humanoid robots in hazardous environments by associating risks with related actions. Another study uses Hierarchical Dirichlet Process HMMs [33] to identify and classify anomalies that arise during collaborative kitting tasks. Yet another work presents a tensor voting-based method combined with support vector machines (SVMs) for classifying surface anomalies using 3D point cloud data [34].…”
Section: Literature Reviewmentioning
confidence: 99%