• DocumentCode
    1501529
  • Title

    Stochastic analysis of the LMS algorithm with a saturation nonlinearity following the adaptive filter output

  • Author

    Costa, Márcio H. ; Bermudez, Jose Carlos M. ; Bershad, Neil J.

  • Author_Institution
    Grupo de Engenharia Biomedica, Univ. Catolica de Pelotas, Pelotas, Brazil
  • Volume
    49
  • Issue
    7
  • fYear
    2001
  • fDate
    7/1/2001 12:00:00 AM
  • Firstpage
    1370
  • Lastpage
    1387
  • Abstract
    This paper presents a statistical analysis of the least mean square (LMS) algorithm with a zero-memory scaled error function nonlinearity following the adaptive filter output. This structure models saturation effects in active noise and active vibration control systems when the acoustic transducers are driven by large amplitude signals. The problem is first defined as a nonlinear signal estimation problem and the mean-square error (MSE) performance surface is studied. Analytical expressions are obtained for the optimum weight vector and the minimum achievable MSE as functions of the saturation. These results are useful for adaptive algorithm design and evaluation. The LMS algorithm behavior with saturation is analyzed for Gaussian inputs and slow adaptation. Deterministic nonlinear recursions are obtained for the time-varying mean weight and MSE behavior. Simplified results are derived for white inputs and small step sizes. Monte Carlo simulations display excellent agreement with the theoretical predictions, even for relatively large step sizes. The new analytical results accurately predict the effect of saturation on the LMS adaptive filter behavior
  • Keywords
    Monte Carlo methods; active noise control; adaptive filters; adaptive signal processing; digital simulation; filtering theory; least mean squares methods; mean square error methods; nonlinear estimation; parameter estimation; statistical analysis; stochastic processes; vibration control; Gaussian inputs; LMS adaptive filter; LMS algorithm; MSE performance surface; Monte Carlo simulations; acoustic transducers; active noise control systems; active vibration control systems; adaptive algorithm design; adaptive filter output; deterministic nonlinear recursions; large amplitude signals; least mean square algorithm; mean-square error performance surface; minimum achievable MSE; nonlinear signal estimation; optimum weight vector; saturation nonlinearity; slow adaptation; small step sizes; stochastic analysis; time-varying mean weight; white inputs; zero-memory scaled error function nonlinearity; Acoustic noise; Active noise reduction; Adaptive filters; Algorithm design and analysis; Least squares approximation; Noise level; Statistical analysis; Stochastic processes; Stochastic resonance; Vibration control;
  • fLanguage
    English
  • Journal_Title
    Signal Processing, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    1053-587X
  • Type

    jour

  • DOI
    10.1109/78.928691
  • Filename
    928691