• DocumentCode
    1144890
  • Title

    Determining hearing threshold from brain stem evoked potentials. Optimizing a neural network to improve classification performance

  • Author

    Alpsan, D. ; Towsey, M. ; Ozdamar, Ozcan ; Tsoi, A. ; Ghista, D.N.

  • Author_Institution
    Dept. of Biophys., United Arab Emirates Univ., Al-Ain, United Arab Emirates
  • Volume
    13
  • Issue
    4
  • fYear
    1994
  • Firstpage
    465
  • Lastpage
    471
  • Abstract
    Feed-forward neural networks in conjunction with back-propagation are an effective tool to automate the classification of biomedical signals. Most of the neural network research to date has been done with a view to accelerate learning speed. In the medical context, however, generalisation may be more important than learning speed. With the brain stem auditory evoked potential classification task described in this study, the authors found that parameter values that gave fastest learning could result in poor generalisation. In order to achieve maximum generalisation, it was necessary to fine tune the neural net for gain, momentum, batch size, and hidden layer size. Although this maximization could be time consuming, especially with larger training sets, the authors´ results suggest that fine tuning parameters can have important clinical consequences, which justifies the time involved. In the authors´ case, fine tuning parameters for high generalisation had the additional effect of reducing false negative classifications, with only a small sacrifice in learning speed.<>
  • Keywords
    bioelectric potentials; brain; hearing; medical signal processing; neural nets; back-propagation; batch size; biomedical signals classification automation; brainstem evoked potentials; classification performance; false negative classifications; hearing threshold determination; hidden layer size; learning speed; neural net fine tuning; neural network optimization; parameter values; Artificial neural networks; Auditory system; Biological neural networks; Biology computing; Current measurement; Electrodes; Neural networks; Scalp; Signal analysis; Signal to noise ratio;
  • fLanguage
    English
  • Journal_Title
    Engineering in Medicine and Biology Magazine, IEEE
  • Publisher
    ieee
  • ISSN
    0739-5175
  • Type

    jour

  • DOI
    10.1109/51.310986
  • Filename
    310986