• DocumentCode
    1091138
  • Title

    Noise Reduction in Rhythmic and Multitrial Biosignals With Applications to Event-Related Potentials

  • Author

    Celka, Patrick ; Le, Khoa N. ; Cutmore, Timothy R H

  • Author_Institution
    Griffith Sch. of Eng., Griffith Univ., Southport, QLD
  • Volume
    55
  • Issue
    7
  • fYear
    2008
  • fDate
    7/1/2008 12:00:00 AM
  • Firstpage
    1809
  • Lastpage
    1821
  • Abstract
    A new noise reduction algorithm is presented for signals displaying repeated patterns or multiple trials. Each pattern is stored in a matrix, forming a set of events, which is termed multievent signal. Each event is considered as an affine transform of a basic template signal that allows for time scaling and shifting. Wavelet transforms, decimated and undecimated, are applied to each event. Noise reduction on the set of coefficients of the transformed events is applied using either wavelet de- noising or principal component analysis (PCA) noise reduction methodologies. The method does not require any manual selection of coefficients. Nonstationary multievent synthetic signals are employed to demonstrate the performance of the method using normalized mean square error against classical wavelet and PCA based algorithms. The new method shows a significant improvement in low SNRs (typically <0 dB). On the experimental side, evoked potentials in a visual oddball paradigm are used. The reduced-noise visual oddball event-related potentials reveal gradual changes in morphology from trial to trial (especially for N1-P2 and N2-P3 waves at Fz), which can be hypothetically linked to attention or decision processes. The new noise reduction method is, thus, shown to be particularly suited for recovering single-event features in non- stationary low SNR multievent contexts.
  • Keywords
    affine transforms; bioelectric phenomena; medical signal processing; principal component analysis; signal denoising; visual evoked potentials; wavelet transforms; affine transform; event related potentials; multievent signal; multitrial biosignal noise reduction; noise reduction algorithm; nonstationary multievent synthetic signals; normalized mean square error; principal component analysis; rhythmic biosignal noise reduction; undecimated wavelet transforms; visual oddball paradigm; wavelet denoising; Additive noise; Australia; Biomedical signal processing; Enterprise resource planning; Fluctuations; Mean square error methods; Morphology; Noise reduction; Principal component analysis; Signal processing; Signal processing algorithms; Signal to noise ratio; Wavelet analysis; Wavelet transforms; Event-related potentials (ERPs); Noise reduction; event-related potentials; noise reduction; principal component analysis; principal component analysis (PCA); rhythmic patterns; visual oddball paradigm; wavelet; Algorithms; Artifacts; Brain; Electroencephalography; Evoked Potentials; Humans; Sensitivity and Specificity;
  • fLanguage
    English
  • Journal_Title
    Biomedical Engineering, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    0018-9294
  • Type

    jour

  • DOI
    10.1109/TBME.2008.919851
  • Filename
    4463654