Istanbul 2004 
network is 
| (e.g, data 
ground data 
sing of data 
) an organic 
and radio 
to specific 
tive facilities 
1999). Thus, 
h-speed data 
with one or 
n high-speed 
and ground 
nary further 
redictions of 
re, pollution 
are then also 
the directly 
o the ground 
et these data 
ocessed data 
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sither direct 
ously by the 
ority, where 
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autonomous 
yrioritization 
ontrollers or 
International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part BI. Istanbul 2004 
The FIEOS will perform much of the event detection and 
response processing that is presently performed by ground- 
based systems, through the use of high performance processing 
architectures and reconfigurable computing environments 
(Alkalai 2001, Armbruster et al. 2000, Bergmann et al. 2000). 
FIEOS will act autonomously in controlling instruments and 
spacecraft, while also responding to the commands of the user 
interested to measure specific events or features. So, users can 
select instrument parameters on demand and control on-board 
algorithms to preprocess the data for information extraction. 
  
Various Users 
  
Illustration 
A real-time user, eg, a | NE X 
mobile GIS user, requires a 
Mobile | real-time downlink for geo- 
user referenced satellite imagery 
with a portable receiver, small 
antenna and laptop computer. 
  
  
A mobile user, e.g., a search- 
Real- | and-rescue pilot, requires a 
time real-time downlink for geo- 
user referenced panchromatic or 
multispectral imagery in a 
helicopter. 
  
A lay user) cæ, a' farmer, 
Lay requires geo-referenced, 
user multispectral imagery at a 
frequency of 1-3 days for 
investigation of his harvest. 
  
A professional user, e.g. a 
Profes | mineralogist, requires 
sional | hyperspectral imagery for 
user distinguishing different 
minerals. 
  
A topographic cartographer, 
Profes | e.g, a  photogrammetrist 
sional | requires panchromatic images 
user for stereo mapping. 
  
  
  
  
  
  
Figure 2. Examples of future direct end-users in the land 
surface remote sensing (images are courtesy of other authors 
available on the web). 
The design concept for FIEOS is flexible because any 
additional satellites can easily be inserted without risk to the 
infrastructure, and the instruments and platforms are 
organically tied together with network information technology. 
A two-layer satellite network insures that global data is 
collected on a frequency of decade minutes base or shorter; 
event-driven data are collected with multi-angle, multi- 
resolution, multi-bands, and users can acquire images of any 
part of the globe in real-time. This design concept provides a 
plug-and-play approach to the development of new sensors, 
measurement platforms and information systems, permitting 
smaller, lighter, standardized satellites with independent 
functions to be designed for shorter operational lifetimes than 
X -X-—f 
veu mat 
today's large systems so that the instrument technology in 
space can be kept closer to the state-of-the-art. 
2.3 End-user operation 
End users expect directly down-linked satellite data (in fact, the 
concept of data means image-based information, rather than 
traditional remotely sensed data) using their own receiving 
equipment. All receivers are capable of uploading the user's 
command, and mobile and portable receivers have GPS 
receivers installed, i.e., mobile user's position in geodetic 
coordinate system can be real-time determined and uploaded to 
satellite systems. The on-board data distributor will retrieve an 
image (scene) from its database according to the user's position 
(Figure 2). 
In this fashion, an ordinary user on the street is able to use a 
portable wireless device to downlink/access the image map of 
the surroundings from a satellite system or from the Internet. 
Homes in the future are also able to obtain atmospheric data 
from the satellite network for monitoring their own 
environments. The operation appears to the end-users as simple 
and easy as selecting a TV channel by using a remote control 
(Figure 3). The intelligent satellite system will enable people 
not only to see their environment, but also to "shape" their 
physical surroundings. 
Geostationary ' 
wr 
     
  
  
  
    
The end-users connect their 
(PC) computer to receiver 
and antenna for real-time 
downlink and display of 
satellite imagery. 
  
  
  
   
    
  
  
  
  
  
   
Remote 
control 
  
  
  
It appears to the end-users that receiving the s? 
ellite data is as easy as selecting a TV channel. 
  
  
Figure 3. End-user operation akin to selecting a TV channel. 
3. STATUS OF PROGRESS AT ODU 
Realization of such a technologically complex system will 
require the contributions of scientists and engineers from many 
disciplines. In the present paper, we report our progress on two 
topics: (1) Relative and absolute navigation of formation flying 
of satellites, and (2) On-board *GCP" identification based on 
GIS data. 
3.1 Simultaneous Determination of R/A Position and 
Attitude of Multi-satellites 
The simultaneous determination of R/A and attitude of multi- 
satellites is based on the photogrammetry collinearity as 
follows: 
M M M M gl M M 
NB =X] ytr =X; pen (2e Le ) 
M M 
no eX. )*t ra (Y; 
A rn - 773 
Pe og A Lu T YN RIZ PZN) (1) 
rU eX yen E: Y RA — ZE )