• DocumentCode
    3402319
  • Title

    Computational intelligence based data fusion algorithm for dynamic sEMG and skeletal muscle force modelling

  • Author

    Potluri, C. ; Anugolu, M. ; Schoen, Marco P. ; Naidu, D. Subbaram ; Urfer, A. ; Rieger, Craig

  • Author_Institution
    Idaho State Univ., Pocatello, ID, USA
  • fYear
    2013
  • fDate
    13-15 Aug. 2013
  • Firstpage
    74
  • Lastpage
    79
  • Abstract
    In this work, an array of three surface Electromyography (sEMG) sensors are used to acquired muscle extension and contraction signals for 18 healthy test subjects. The skeletal muscle force is estimated using the acquired sEMG signals and a Non-linear Wiener Hammerstein model, relating the two signals in a dynamic fashion. The model is obtained from using System Identification (SI) algorithm. The obtained force models for each sensor are fused using a proposed fuzzy logic concept with the intent to improve the force estimation accuracy and resilience to sensor failure or misalignment. For the fuzzy logic inference system, the sEMG entropy, the relative error, and the correlation of the force signals are considered for defining the membership functions. The proposed fusion algorithm yields an average of 92.49% correlation between the actual force and the overall estimated force output. In addition, the proposed fusion-based approach is implemented on a test platform. Experiments indicate an improvement in finger/hand force estimation.
  • Keywords
    biosensors; electromyography; entropy; fuzzy logic; fuzzy reasoning; medical signal processing; sensor fusion; SI algorithm; computational intelligence; contraction signal acquisition; data fusion algorithm; finger force estimation; force estimation; force signal correlation; force signal relative error; fuzzy logic concept; fuzzy logic inference system; hand force estimation; membership functions; muscle extension signal acquisition; nonlinear Wiener Hammerstein model; sEMG entropy; sEMG sensors; sEMG signals; sensor failure; sensor misalignment; skeletal muscle force modelling; surface electromyography sensors; system identification algorithm; Algorithm design and analysis; Computational modeling; Entropy; Force; Fuzzy logic; Muscles; Sensors; Approximate Entropy; Data fusion; Fuzzy logic;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Resilient Control Systems (ISRCS), 2013 6th International Symposium on
  • Conference_Location
    San Francisco, CA
  • Type

    conf

  • DOI
    10.1109/ISRCS.2013.6623754
  • Filename
    6623754