Towards Stochastic Fault-Tolerant Control Using Precision Learning and Active Inference

Conference paper (2022)

Authors

Mohamed Baioumy University of Oxford
C. Pezzato Robot Dynamics - Mechanical, Maritime and Materials Engineering
Carlos Hernández Robot Dynamics - Mechanical, Maritime and Materials Engineering
Nick Hawes University of Oxford
Riccardo M.G. Ferrari Team Riccardo Ferrari - Mechanical, Maritime and Materials Engineering
Research Group
Robot Dynamics (Mechanical, Maritime and Materials Engineering) (TU Delft)
Copyright: © 2022 Mohamed Baioumy, C. Pezzato, Carlos Hernández, Nick Hawes, Riccardo M.G. Ferrari
DOI: https://doi.org/10.1007/978-3-030-93736-2_48
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Published Date

2022

Language

English

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Faculty

Mechanical, Maritime and Materials Engineering

Department

Cognitive Robotics

Research Group

Robot Dynamics

Abstract

This work presents a fault-tolerant control scheme for sensory faults in robotic manipulators based on active inference. In the majority of existing schemes a binary decision of whether a sensor is healthy (functional) or faulty is made based on measured data. The decision boundary is called a threshold and it is usually deterministic. Following a faulty decision, fault recovery is obtained by excluding the malfunctioning sensor. We propose a stochastic fault-tolerant scheme based on active inference and precision learning which does not require a priori threshold definitions to trigger fault recovery. Instead, the sensor precision, which represents its health status, is learned online in a model-free way allowing the system to gradually, and not abruptly exclude a failing unit. Experiments on a robotic manipulator show promising results and directions for future work are discussed.

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