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International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B7. Istanbul 2004 
2.2 Field surveys 
In 2003 field surveys were organized similarly as the field 
surveys in the Radarsat-1 study in 2001. Purpose of the field 
surveys is naturally to have reference data for the analysis of 
SAR backscattering time series. Due to the limited time 
window, which in our case was +3 hour compared with actual 
image acquisition, we had to select a small set of test parcels for 
more detailed research. Thereby 24 parcels was chosen and 
following information was surveyed for each of the parcel: 
= Soil surface roughness 
=» Seed row direction 
= Soil surface moisture 
= Crop height and growth stage 
= Possible crop yield damages 
Soil surface roughness was measured using Leica laser 
distometer only once in the beginning of the growing season 
and after that roughness was assumed to be constant during the 
growing season. Soil surface moisture was measured using 
ThetaKit TK2-BASIC soil moisture measuring device, which 
measures volumetric moisture into the depth of 6 cm. Crop 
height was simply measured using measuring tape. Crop yield 
damages were mapped as they were found during the field 
surveys. Time series of the soil surface moisture for the 24 test 
parcels are given in Figure 4. 
  
Soil Surface Moisture 
e 
e 
Volumetric soil moisture % 
RB 
e 
UN 
IN 
"X 
  
  
  
20 Ke. m ESS Es | 
SK 7 E a = i 
10 Ew | 
| 
0 : : : 
8-Jun-03 8-Jul-03 7-Aug-03 6-Sep-03 
Date 
  
  
  
Figure 4. Volumetric soil surface moisture for test parcels in 
summer 2003. 
3. RESULTS 
3.1 Envisat SAR backscattering time series in 2003 
In Figure 3 is represented the Envisat SAR backscattering time 
series in VV and VH polarizations for all major cultivated 
plants in the test area in summer 2003. Similar results were 
obtained for Radarsat-1 SAR in HH polarization in summer 
2001 (Karjalainen et.al., 2003). Naturally results from years 
2001 and 2003 are not directly comparable due to the changing 
weather conditions, but nevertheless, a general comparison of 
the usability of Radarsat-1 and Envisat SAR images in 
agricultural monitoring can be made. 
In the beginning of the growing season, before sowing, 
ploughed fields had relatively rough soil surface and 
consequently backscattering values were higher than in sowed 
fields. According to Radarsat-1 results in 2001, HH 
backscattering for ploughed fields was approximately from —8 
to even —4 dB. Backscattering variation was high in ploughed 
fields due to the surface roughness and soil moisture variations. 
After sowing, backscattering decreased, because sowing made 
the soil surface smoother compared to the ploughed fields. 
After sowing, VH backscattering was near -18 dB, but VV 
backscattering was still as high as —10 dB, and reason for this 
most likely is that VV polarization is more sensitive to the soil 
surface moisture, which at same time is around 40% of 
volumetric moisture. Soil surface moisture rapidly decreased by 
the beginning of July as can be seen in Figure 4. and 
simultaneously VV backscattering decreased to it minimum 
around -14 dB for cereal crops. 
It should be noticed that the noise equivalent o" for Envisat 
alternating polarization images is from -19 to -22 dB 
depending on the antenna look angle (ESA, 2002). From 
backscattering time series in Figure 3, can be scen that in the 
beginning of the growing season VH backscattering was close 
to the noise equivalent o" and VH backscattering started to 
increase only after the middle of July, which implies that the 
early crop growth from emerging to 50 cm cannot be seen using 
Envisat cross-polarization images. 
For cereal crops both VV and VH backscattering gradually 
started to increase in the middle of July when crop height was 
approximately 50 cm. After this point of time soil surface 
moisture stayed relatively constant from 10% to 30% of 
volumetric moisture, thus the average increase in SAR 
backscattering seemed to be caused by the increase of the 
vegetation biomass. Similar results were obtained for Radarsat- 
1 HH polarization SAR images in 2001. The increase of SAR 
backscattering was from 2 to 4 dB depending on the crop 
species and SAR polarization. According to these results it 
seemed that cross-polarization i.e. VH polarization might be the 
best choice for biomass detection in Finland for cereal crops. 
but noise equivalent o" in Envisat SAR images is too high for 
detecting crops with low biomass. Also, it should be 
emphasized that averaging of relatively large areas of same 
crops is needed since the radiometric accuracy of alternating 
polarization images makes it hard to see backscattering changes 
for individual parcels with small area compared to the spatial 
resolution of 30 m. 
The backscattering time series for cereal crops can be explained 
fairly well, but for other species it is more difficult. For example 
grass silage can be harvested many times per growing season 
depending on the weather conditions. Also turnip rape and 
potato have quite unique time series, which on the other hand 
makes classification or identification of crop species possible. 
For example potato fields have relatively high backscattering 
throughout the growing season in VV polarization most likely 
due to the much more rough soil surface than cereal crops have. 
3.2 Detection of yield damages 
In 2001, we concluded that crop yield damages caused by 
lodging could not be detected using Radarsat-1 HH polarization 
SAR images. Only one barley field out of totally 41 fields with 
lodging was possible to be identified from Radarsat-1 SAR 
images. We believed that HH polarization used in Radarsat-1 
SAR images was not sensitive enough to see changes in the 
crop vegetation biomass. When Envisat SAR images were used 
in 2003, we detected 8 parcels where more than 50% of the 
crops where flattened by lodging. The lodging usually happens