2019
DOI: 10.3390/app9061072
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A Latent State-Based Multimodal Execution Monitor with Anomaly Detection and Classification for Robot Introspection

Abstract: Robot introspection is expected to greatly aid longer-term autonomy of autonomous manipulation systems. By equipping robots with abilities that allow them to assess the quality of their sensory data, robots can detect and classify anomalies and recover appropriately from common anomalies. This work builds on our previous Sense-Plan-Act-Introspect-Recover (SPAIR) system. We introduce an improved anomaly detector that exploits latent states to monitor anomaly occurrence when robots collaborate with humans in sha… Show more

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Cited by 24 publications
(15 citation statements)
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“…Such a strategy could allow human operators to aid in difficult navigation or identification tasks for multiple robots without incurring the full cognitive load burden of direct teleoperation. Leveraging learned models of human preferences (i.e., when in a given scenario they would most likely take over direct teleoperation of an agent) [67,68] and learned models of when robots are likely to require intervention (e.g., by assessing incoming sensory data for statistical anomalies [69] or by incorporating human control expected utility into a learned policy [70]) in order to automate the sliding autonomy control handoff could further reduce operator training requirements and attention burden.…”
Section: Human-robot Interaction (Hri)mentioning
confidence: 99%
“…Such a strategy could allow human operators to aid in difficult navigation or identification tasks for multiple robots without incurring the full cognitive load burden of direct teleoperation. Leveraging learned models of human preferences (i.e., when in a given scenario they would most likely take over direct teleoperation of an agent) [67,68] and learned models of when robots are likely to require intervention (e.g., by assessing incoming sensory data for statistical anomalies [69] or by incorporating human control expected utility into a learned policy [70]) in order to automate the sliding autonomy control handoff could further reduce operator training requirements and attention burden.…”
Section: Human-robot Interaction (Hri)mentioning
confidence: 99%
“…The knowledge-based models, diminished the need for data and labeling. In [14], the sticky version of HDP was used along a vector autoregressive observation model to do anomaly identification and multi-class classification with a dynamic threshold that updates its parameters according to the latent state of a sub-task. In [15], anomaly identification was conducted with HMMs whose detection threshold varied according to clusters of execution progress.…”
Section: Anomaly Identification and Classificationmentioning
confidence: 99%
“…Obviously, when these four parameters are known, the method is computationally feasible. The detailed options is assigned in Section IV through experiments and more detailed derivation process of the formulation can be found in our previous work [19]. So for, we can model the underlying dynamics from a set of unstructured demonstrations such that the problem turns into how to learn the unknown parameters in approximate fashion?…”
Section: ) Bayesian Nonparametric Time Series Learningmentioning
confidence: 99%
“…, K } denotes how many times of movement B i is successfully executed. Therefore, the probability mass function of transition p(T B i ,B * ) is formulated as a multinomial distribution that model a total N = i=K i=1 N i reverse executions, that is, (19) where, θ i indicates the probability of movement primitive B i is selected, which subject to θ i ∈ [0, 1] and K i=1 θ i = 1. Therefore, we use the multinomial distribution not only to intuitively depict the expectation of human intention on the recovery behavior when an abnormal occurrence is detected in human robot interaction scenarios, but also to provide an indirect way to express the intuitive understanding of human for expecting the motion of the robot end-effector, the related manipulation objects as well as the complex relationship between ''human-robot-environment''.…”
Section: A Reverse Executionmentioning
confidence: 99%
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