Title :
Wheat cycle monitoring using radar data and a neural network trained by a model
Author :
Del Frate, Fabio ; Ferrazzoli, Paolo ; Guerriero, Leila ; Strozzi, Tazio ; Wegmüller, Urs ; Cookmartin, Geoff ; Quegan, Shaun
Author_Institution :
Dipt. di Informatica, Univ. of Rome "Tor Vergata", Italy
Abstract :
This paper describes an algorithm aimed at monitoring the soil moisture and the growth cycle of wheat fields using radar data. The algorithm is based on neural networks trained by model simulations and multitemporal ground data measured on fields taken as a reference. The backscatter of wheat canopies is modeled by a discrete approach, based on the radiative transfer theory and including multiple scattering effects. European Remote Sensing satellite synthetic aperture radar signatures and detailed ground truth, collected over wheat fields at the Great Driffield (U.K.) site, are used to test the model and train the networks. Multitemporal, multifrequency data collected by the Radiometer-Scatterometer (RASAM) instrument at the Central Plain site are used to test the retrieval algorithm.
Keywords :
agriculture; crops; neural nets; radiative transfer; remote sensing by radar; soil; synthetic aperture radar; vegetation mapping; Central Plain site; European Remote Sensing satellite; Great Driffield; RASAM instrument; Radiometer-Scatterometer instrument; UK; USA; United Kingdom; crops; detailed ground truth; discrete approach; model simulations; multifrequency data; multiple scattering effects; multitemporal data; multitemporal ground data; neural network; radar data; radiative transfer theory; retrieval algorithm; scattering model; soil moisture; synthetic aperture radar; wheat canopy backscattering; wheat cycle monitoring; wheat fields; Backscatter; Monitoring; Neural networks; Radar remote sensing; Radar scattering; Remote sensing; Soil measurements; Soil moisture; Spaceborne radar; Testing;
Journal_Title :
Geoscience and Remote Sensing, IEEE Transactions on
DOI :
10.1109/TGRS.2003.817200
