International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B7. Istanbul 2004 
the scan and can be calculated from the along-track distance on 
the ground and the satellite velocity after Lorenz (1985). For 
MISR, the time difference for different cross-track positions 
within a block or scene can be assumed as constant. Northerly 
winds lead to an underestimation of the heights and the along- 
track wind component has to be added to the y-parallax, while 
southerly winds result in overestimation of cloud-top heights. 
The motion vectors retrieved from Meteosat-6 and Meteosat-7 
data were resampled to the ATSR2 or MISR grid and the cross- 
and along-track wind components calculated. Using the time 
difference between the acquisition of the two views, the along- 
track wind components were converted into CTH corrections. 
3. VALIDATION 
As each observation and each retrieval method have its own 
characteristics, much can be learned from a intercomparison of 
the results. The objective is to document the relative 
performance of the different observations of cloud top height, 
and where possible to understand this. In collaboration with 
Eumetsat and the Rutherford Appleton Laboratory (RAL), two 
case studies were analyzed with spaceborne observations from 
ATSR2, MISR and  Meteosat-6/-7 and ground-based 
observations by the Chilbolton radar and radiosondes. The 
results are summarized in Table 2; the retrieval methodologies 
(next to our stereo processing) are described in detail in 
Tjemkes et al. (2002). 
  
Date ATSR2 MISR Radar Radiosonde 
28/06/2000 235: 02 24+0.2 |2.48+0.03/2.5+0.2 
13/06/2001 4.5 € 0.3 4.4+0.2 14.27 + 0.08 14.6 + 0.2 
Table 2. CTH results (in km above sea-level) from ATSR2, 
MISR, radar and radiosondes for two cases (20 June 
2000 and 13 June 2001) over Chilbolton, UK. 
  
  
  
  
  
  
  
  
  
Based on the validation experience from Cloudmap2, a new 
comparison study of cloud height assignment methods has been 
started by Eumetsat in November 2003. Next to the multi-view 
photogrammetric retrieval from MISR and AATSR, the cloud 
height will be determined by optimal estimation from AATSR 
(by RAL), CO; slicing from MODIS and Oxygen A-band from 
MERIS (by Free University Berlin). The comparison of these 
different height products with the operational Eumetsat AMV 
(Atmospheric Motion Vector) product will allow to evaluate the 
strengths and weaknesses of each individual height assignment 
method within the AMV production chain. Results from Phase 
| of the study are reported in Fischer et al. (2004). 
4. COMBINATION WITH GROUND-BASED STEREO 
DATA 
For the acquisition of ground-based stereo images of clouds, a 
camera imager system has been developed (Figure 2). The 
system, data acquisition and data processing is described in 
detail in Seiz et al. (2002). The imager system was part of the 
MAP-Special Observation Period (SOP) composite observing 
system at the Rhine Valley, Switzerland, in autumn 1999 and 
was later installed at the Ziirich-Kloten airport in September 
2001 and April 2002. The system was used for the retrieval of 
cloud-bottom heights, which were then used for the validation 
of stereo cloud-top heights of vertically thin clouds (e.g. cirrus, 
contrails) and for the combination of cloud-bottom boundaries 
with satellite-derived cloud-top boundaries for a 3D 
representation of the current cloud field. This second 
application is explained in the next section. 
  
  
* 
Figure 2. Ground-based imager system (Skycam). 
4.1 Combination of Satellite- and Ground-based Datasets 
For assimilation experiments with a very high-resolution 
version of the operational NWP model at MeteoSwiss, several 
Skycam measurements series were performed at Zurich-Kloten 
airport in April 2002, in coincidence with satellite (ASTER, 
MISR) overpasses. In collaboration with the German Aerospace 
Center (DLR), a 3D cloud data set was then derived from the 
combination of MISR stereo cloud-top heights, MODIS 
microphysical data and Skycam stereo cloud-bottom heights. 
On a 50 m x 50 m grid, the cloud geometry was defined by the 
cloud mask and the cloud-bottom heights from Skycam and by 
the cloud-top heights from MISR. According to the effective 
radius reached close to the cloud top and the total optical 
thickness (both from MODIS MODO6 data), a constant liquid 
water gain and a droplet number density could be derived for 
each cloudy column. Thus, an internal profile of microphysics 
of a vertical resolution of 50 m was achieved (Figure 3). More 
details about the 3D cloud boundary extraction and subsequent 
application in radiative transfer simulations at DLR can be 
found in Seiz (2003) and in the Cloudmap2 Final Report, 
D13/D14 (Cloudmap2, 2004). 
  
T-Ronge (af 
  
Q 
Rr T 
Y [km] 0 
X [km] 
Figure 3. 3D cloud water distribution, derived from 3D cloud 
boundary data (MISR, ground-based camera system) 
and MODIS information, 19 April 2002 (image 
courtesy: Tobias Zinner, DLR). 
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