• DocumentCode
    3663798
  • Title

    Fault detection in linear electromagnetic actuators using time and time-frequency-domain features based on current and voltage measurements

  • Author

    Christian Knöbel;Zakaria Marsil;Markus Rekla;Johannes Reuter; Gühmann

  • Author_Institution
    Institute of System Dynamics, University of Applied Sciences Konstanz, Konstanz, Germany
  • fYear
    2015
  • Firstpage
    547
  • Lastpage
    552
  • Abstract
    In this paper an approach towards databased fault diagnosis of linear electromagnetic actuators is presented. Time and time-frequency-domain methods were applied to extract fault related features from current and voltage measurements. The resulting features were transformed to enhance class separability using either Principal Component Analysis (PCA) or Optimal Transformation. Feature selection and dimensionality reduction was performed employing a modified Fisher-ratio. Fault detection was carried out using a Support-Vector-Machine classifier trained with randomly selected data subsets. Results showed, that not only the used feature sets (time-domain/time-frequency-domain) are crucial for fault detection and classification, but also feature pre-processing. PCA transformed time-domain features allow fault detection and classification without misclassification, relying on current and voltage measurements making two sensors necessary to generate the data. Optimal transformed time-frequency-domain features allow a misclassification free result as well, but as they are calculated from current measurements only, a dedicated voltage sensor is not necessary. Using those features is a promising alternative even for detecting purely supply voltage related faults.
  • Keywords
    "Principal component analysis","Feature extraction","Voltage measurement","Actuators","Covariance matrices","Current measurement","Circuit faults"
  • Publisher
    ieee
  • Conference_Titel
    Methods and Models in Automation and Robotics (MMAR), 2015 20th International Conference on
  • Type

    conf

  • DOI
    10.1109/MMAR.2015.7283934
  • Filename
    7283934