1181
4.3 The Combination of Optical and Radar Remote Sensing
In this section, LAI estimates from the three CAESAR recordings and the two AIRSAR recordings are integrated
and, with their appropriate weight factors, used for calibrating SUCROS. Results are given in table 2 for the
three CAESAR recordings in combination with L-band HH and C-band VV radar data. The comparison between
estimated and actual yield is given in figure 6. On the average, the simulation error of (fresh) beet yield was
3.0 t/ha (4.2% error) for L-band HH and 3.5 t/ha (4.8% error) for C-band VV, respectively. This error is clearly
smaller than the one obtained for the three CAESAR recording dates only and of the same magnitude as the errors
obtained using time-series of CROPSCAN (optical) measurements during the whole growing season. These results
indicate a synergistic effect (see table 2) by using both optical and radar data for crop growth monitoring. However,
under practical conditions only very few optical data during the growing season will be available. For instance,
when no optical data from July 4th would be available it is to be expected that radar data from the beginning
of July offer a significant improvement to the monitoring of crop growth, particularly at the beginning of the
growing season.
As mentioned before, another potential advantage of radar measurements lies in the possibility of obtaining
information about crop structure changes. The latter may be related to important transitions in crop growth stage.
(b)
estimated beet yield
actual beet yield (tons/ha)
Figure 6. Comparison between estimated yield and actual yield for three CAESAR recording dates and for two
AIRSAR recordings in L-band HH polarization (a) and C-band W-polarization (b).
5 - DISCUSSION AND CONCLUSIONS
For simultaneous (contemporary) observations no synergy occurred in the estimation of LAI. Optical data were
most suitable. Calibration of the Cloud model at one date (contemporary) is possible using optical data if enough
fields are available for the calibration and the between-field variation is large.
For operational applications the assumption of non-simultaneous observations is most realistic. For sugar
beet, radar data can only be used for estimating LAI early in the growing season (before crop closure). This may
be called a model-based approach. After crop closure, radar backscatter is determined by crop architecture (leaf
angle distribution). However, this still may yield important information for crop growth monitoring. Using the
latter information may be called a feature-based approach.
Results for sugar beet indicated that, when a time-series of optical recordings is available, LAI can be monitored
well and a good estimate of sugar beet yield at the end of the season is possible by using a calibrated crop growth
model. When only a few recording dates with an optical sensor are available, radar recordings at L-band HH-
polarization or C-band VV-polarization gave a slight improvement of the results of crop monitoring and yield
estimation in comparison to the optical data only. This confirms that the main advantage of radar lies in the possibility
to acquire information on crop growth when other techniques (in particular optical techniques) fail.
Different scenarios with various combinations of optical and radar data at various dates during the growing
season for sugar beet still must be evaluated further in order to obtain an accurate picture of the significance of
radar data (in a model-based and feature-based approach) for crop growth monitoring. The technique to calibrate
a crop growth model with remote sensing data was developed for sugar beet in Flevoland. The behaviour of other
crops (other varieties, other locations) can be quite different. The developed techniques, therefore, have to be
