Dynamic Neural Networks for Motion-Force Control of Redundant Manipulators: An Optimization Perspective

Nonparametric Bayesian Learning for Collaborative Robot Multimodal Introspection

et al. 2020

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In this chapter, we introduce an anomaly monitoring pipeline using the Bayesian nonparametric hidden Markov models after the task representation and skill identification in previous chapter, which divided into three categories according to different thresholds definition, including (i) log-likelihood-based threshold, (ii) threshold based on the gradient of log-likelihood, and (iii) computing the threshold by mapping latent state to log-likelihood. Those method are effectively implement the anomaly monitoring during robot manipulation task. We also evaluate and analyse the performance and results for each method, respectively.

Section: Related Workmentioning

confidence: 99%

Nonparametric Bayesian Method for Robot Anomaly Monitoring

Nonparametric Bayesian Learning for Collaborative Robot Multimodal Introspection

et al. 2020

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“…Therefore, how to correctly select the next motion primitive after the execution of the current motion primitive is another research difficulty of the complex task description of the robot. In response to the serialization of motion primitives, Pastor et al [27] proposed a motion description based on the Associative Skill Memories (ASM) of DMP motion primitives for motion selection, which differ from the control scheme [31]. Statistical data such as mean and variance are saved at all times.…”

Section: Related Workmentioning

confidence: 99%

Incremental Learning Robot Task Representation and Identification

Nonparametric Bayesian Learning for Collaborative Robot Multimodal Introspection

et al. 2020

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In this chapter, we present a novel method for incremental learning robot complex task representation, identifying repeated skills, and generalizing to new environment by heuristically segmenting the unstructured demonstrations into movement primitives that modelled with a dynamical system. The proposed method combines the advantages of recent task representation methods for learning from demonstration in into an integrated framework. In particular, we use the combination of finite state machine and dynamical movement primitives for complex task representation, and investigate the Bayesian nonparametric hidden Markov model for repeated skill identification. To this end, a robot should be able to identify its actions not only when failure or novelty occurs, but also as it executes any number of skills, which helps a robot understand what it is doing at all times. Two complex, multi-step robot tasks are designed to evaluate the feasibility and effectiveness of proposed methods. We not only present the results in task representation, but also analyzing the performance of skill identification by various nonparametric models with various modality combinations.

“…Then, it formulates a task execution plan, and finally executes this plan. However, the control framework is difficult to meet the increasingly complex robot operation tasks in unstructured dynamic environments [20,23]. In the recent decades, increasing the robot multi-modal introspection and anomaly recovery policy after the robot execution would be an effective way to address the aforementioned issues.…”

Section: Background and Significancementioning

confidence: 99%

Introduction to Robot Introspection

Nonparametric Bayesian Learning for Collaborative Robot Multimodal Introspection

et al. 2020

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In this chapter, we mainly introduce the definition, background, significance, and the start-of-the-art methods of collaborative robot multimodal introspection. The current issues of robot introspection are also introduced, which including the complex task representation, anomaly monitoring, diagnoses and recovery by assessing the quality of multimodal sensory data during robot manipulation. The overall content of this book is presented at the end.