• DocumentCode
    990629
  • Title

    Multiparameter inversion of a layer of vegetation canopy over rough surface from the system response function based on the mueller matrix solution of pulse echoes

  • Author

    Xu, Feng ; Jin, Ya-Qiu

  • Author_Institution
    Key Lab., Fudan Univ., Shanghai
  • Volume
    44
  • Issue
    7
  • fYear
    2006
  • fDate
    7/1/2006 12:00:00 AM
  • Firstpage
    2003
  • Lastpage
    2015
  • Abstract
    Under a polarized pulse wave incidence, the temporal Mueller matrix solution from vector radiative transfer (VRT) equation for a layer of nonspherical particles above randomly rough surface is constructed. The system response function based on the Mueller matrix solution is developed, which takes into account the scattering intensity matrix of the canopy, attenuation coefficient matrix through the canopy, scattering intensity matrix of underlying ground surface, and echoes time delay. This system response model preserves consistence with the Mueller matrix solution. To evaluate the system response function from the wave profiles of the received pulse echoes, an adaptive nonlinear estimation method (ALM) is proposed. When the pulse echoes are received, it yields the system response function, i.e., four system parameters. These system parameters are used to invert multiparameters of the vegetation canopy and underlying rough surface, which include the canopy depth, scatterers size, orientation, density and dielectric constant, and the surface roughness and dielectric constant. Numerical examples show good performance of our method as a tractable approach for multiparameters inversion. Potential application and some issues of multiparameters inversion are discussed. An envisaged sensor and platform for practical realization is proposed
  • Keywords
    geophysical signal processing; least mean squares methods; vegetation mapping; Mueller matrix solution; adaptive nonlinear estimation method; attenuation coefficient matrix; canopy depth; dielectric constant; multiparameter inversion; nonspherical particles; polarimetric pulse echoes; pulse wave incidence; rough surface; scatterer density; scatterer orientation; scatterer size; scattering intensity matrix; surface roughness; system response function; vector radiative transfer equation; vegetation canopy; Attenuation; Delay effects; Dielectric constant; Equations; Particle scattering; Polarization; Rough surfaces; Surface roughness; Surface waves; Vegetation; Adaptive nonlinear estimation method (ALM); multiparameter inversion; polarimetric pulse echoes; system response function; vector radiative transfer (VRT);
  • fLanguage
    English
  • Journal_Title
    Geoscience and Remote Sensing, IEEE Transactions on
  • Publisher
    ieee
  • ISSN
    0196-2892
  • Type

    jour

  • DOI
    10.1109/TGRS.2006.870406
  • Filename
    1645309