• DocumentCode
    614326
  • Title

    Legendre based equalization for nonlinear wireless communication channels

  • Author

    Ali, Hazem H. ; Haweel, Mohammed T.

  • Author_Institution
    Commun. & Electron. Dept, Arab Acad. for Sci. & Technol. (AAST), Cairo, Egypt
  • fYear
    2013
  • fDate
    27-30 April 2013
  • Firstpage
    1
  • Lastpage
    4
  • Abstract
    [This paper has been withdrawn by the publisher]. A nonlinear adaptive channel equalizer in a wireless digital communication system is presented. The proposed Legendre equalizer (LE) employs Legendre functional expansion as in the single-layer functional-link ANN (FLANN) to expand the input space into a higher dimension. Unlike the conventional FLANN, the LE employs linear transfer functions at the output neurons rather than the nonlinear sigmoid or hyperbolic tangent transfer functions. This provides the proposed LE with the advantage of providing explicit formula relating the input and target patterns. It also removes back propagation needed in the adaptation of the conventional FLANN and consequently speeds up convergence and reduces the computational requirements. Training the proposed LE is performed using the fast gradient based LMS signed algorithm. A comparison between the proposed LE, linear FIR and FLANN based equalizers is demonstrated. The performance indicator is the bit error rate at different channel and nonlinearity models with additive white Gaussian noise.
  • Keywords
    AWGN; adaptive equalisers; backpropagation; error statistics; least mean squares methods; neural nets; polynomials; telecommunication computing; transfer functions; wireless channels; FLANN; Legendre based equalization; Legendre equalizer; Legendre functional expansion; additive white Gaussian noise; backpropagation; bit error rate; fast gradient based LMS signed algorithm; hyperbolic tangent transfer functions; linear transfer functions; nonlinear adaptive channel equalizer; nonlinear sigmoid transfer functions; single-layer functional-link ANN; wireless digital communication system; Artificial neural networks; Bit error rate; Digital communication; Equalizers; Polynomials; Training; Wireless communication; Legendre polynomials; neural networks; nonlinear equalizers; wireless communications;
  • fLanguage
    English
  • Publisher
    ieee
  • Conference_Titel
    Electronics, Communications and Photonics Conference (SIECPC), 2013 Saudi International
  • Conference_Location
    Fira
  • Print_ISBN
    978-1-4673-6196-5
  • Electronic_ISBN
    978-1-4673-6194-1
  • Type

    conf

  • DOI
    10.1109/SIECPC.2013.6550776
  • Filename
    6550776