of these 
e ground 
'hannels. 
h of 220 
of four 
n in the 
°k stereo 
and two 
ax 15m 
°tween a 
ratio. In 
modules 
module, 
aneously 
h of the 
ruct high 
1e sensor 
984). An 
Models 
mann et 
> camera 
wee line 
of high 
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d DTM's 
satellite 
s: 
  
Nadir -21.4? indiined 
    
f = 220 mm 
f= 237 mm 
Nadir 
  
f= 237 mm f= 220 mm 
    
f= 660 mm 
  
+ 21.4° indined 
  
  
  
Fig. 3:  MOMS-02/2P optical concept 
Merging of panchromatic high resolution (5 m) with 
multispectral (15 m) proved to gain optimal result for thematic 
evaluation and allowed to resolve spectral signatures in the 
mix-pixel domain of the lower resolving multispectral pixels 
for targets with small scaled surface pattern. 
From a technical point of view MOMS-02/2P is today the most 
advanced sensor in optical remote sensing due to the 
combination of high resolution stereo and multispectral data. 
The definition of the four spectral bands of MOMS-02/2P 
allows more seperability, especially for vegetation in 
comparison with other satellite sensors. The high redundancy 
between the green and red bands, as it occurs with TM, SPOT 
HRV and IRS 1C could be avoided. On the other side the 
Indian Remote Sensing satellite IRS 1C, which was launched 
in December 1995, meets very good performances concerning 
the resolution (Fig. 1). 
The definition of the width and location of the spectral bands 
of the MOMS camera is based on spectral signatures of 
relevant objects, mainly vegetation and Fe-bearing rocks and 
soils. The definition of the panchromatic band was based on 
the differences of apparent albedo of soils versus vegetation 
due to the steep increase of reflectance at the "red edge" of 
vegetation. 
In the following the spectral characteristics of the multispectral 
and panchromatic bands are summerized (see Figure 4). Band 
1 covers the blue absorption of vegetation and allows good 
penetration in water bodies. Additionally it includes the right 
wing of the charge transfer band for Fe-bearing rocks and soils. 
Band 2 is centred on the "green peak" of vegetation. This 
position allows to avoid the high correlation between the green 
and the red bands. Band 3, only 32 nm wide, lies exactly in the 
principal absorption of chlorophyll-a in the red wavelength 
region. This enables the acquisition of precise reflectance 
values at the "red edge", an important indicator for the 
detection of vegetation stress. Band 4 was defined on the 
infrared plateau of vegetation between two significant water 
absorption bands. This position guarantees exact reflectance 
values for the maximum infrared reflectance of vegetation. 
This band is also centred for the charge transfer absorption of 
iron. 
The panchromatic high resolution and stereo bands (Fig 4) are 
defined to get most contrast between albedo of vegetation and 
of non vegetated targets (rocks, soils and sealed areas). The 
short-wave end of the panchromatic band is placed to avoid 
most of the noise and lowpass characteristics introduced by 
atmospheric scattering, but also allows some penetration of 
water bodies. The long wave edge was determined to enclose 
the steep raise of vegetation reflectance at the "red edge". 
  
  
0.5% 8 7] 
04 — 
0.3 : -] 
W/m: nm 
Qt - 
  
00 —l 
  
  
MOMS-02/2P 
Panchromatic 
  
  
  
MOMS-02/2P 
Multispectral 
  
  
  
  
  
  
  
  
0.7 
Wavelength[ m ] 
  
  
Fig. 4: Position and Width of the MOMS-02/2P spectral and panchromatic bands 
23 
International Archives of Photogrammetry and Remote Sensing. Vol. XXXI, Part B6. Vienna 1996