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2.3 Combined Use of Contemporary Optical and Radar Data
When looking at the results in section 2.2, it is striking that the standard deviation of LAI estimation from radar
becomes quite laige already at small LAI values. This is quite contrary to the situation in the optical domain as
described in section 2.1. The comparison between standard deviations of LAI estimates from optical and radar
measurements is illustrated in figure 3. This figure clearly illustrates that the accuracy of LAI estimation from
radar measurements is much worse than from optical measurements except for very low LAI values. So, only
little additional value is to be expected from radar measurements for LAI estimation when optical measurements
are available and no synergy occurs in the estimation of LAI.
The significance of radar measurements lies in the possibility of obtaining information about crop growth
at periods that optical remote sensing is not possible from a practical point of view (mainly caused by bad weather
conditions) and in the possibility of obtaining information about the plant structure. Therefore, in the rest of the
study emphasis is put on monitoring the growth of crops in a dynamical way using grcwth models (non-contemporary
approach). However, it must be noted that the above-described contemporary approach does yield synergy in
the way that optical remote sensing measurements are used for calibrating the Cloud model, which would not
have been possible without optical data in this study.
L—band HH —pol.
(b) C —band W-pol.
Figure 3. Comparison of standard deviations of LAI estimates from optical and radar measurements, (a) L-band
HH-polarization; (b) C-band W-polarization.
3 - DYNAMICAL MODELLING OF CROP GROWTH
3.1 Crop Growth Models
Since the 19th century, agricultural researchers have used modelling as a tool to describe relationships between
crop growth (yield) and environmental fee tors such as solar irradiation, temperature and water and nutrient availability.
The models compute the daily growth and development rate of a crop, simulating the dry matter production from
emergence till maturity. Finally, a simulation of yield at harvest time is obtained. The basis for the calculations
of dry matter production is the rate of gross C0 2 assimilation of the canopy. Input data requirements concern
mainly crop physiological characteristics, site characteristics, environmental characteristics and the initial conditions
defined by the date at which the crop emerges.
SUCROS (Simplified and Universal Crop Growth Simulator, Spitters et al., 1989) is a mechanistic crop growth
model that describes the potential growth of a crop from irradiation, air temperature and crop characteristics.
Potential grcwth means the accumulation of dry matter under ample supply of water and nutrients, in an environment
that is free from pests and diseases. The light profile within a crop canopy is computed on the basis of the LAI
and the extinction coefficient. At selected times during the day and at selected depths within the canopy, photosynthesis
is calculated from the photosynthesis-light response of individual leaves. Integration over the canopy layers and
over time within the day gives the daily assimilation rate of the crop (partly from Spitters et al., 1989). Assimilated
matter is first used to maintain the present biomass (maintenance respiration) and for the remainder converted
into new, structural plant matter (with loss due to growth respiration). The newly formed dry matter is partitioned
