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One Scene=60km*60km 
VNIR 
Visible Near Infrared Radiometer 
Wave Length: [F 3 Bands {Backward 
@ @ Q9 052» 0.86 um 
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SWIR 
Short Wave Infrared Radiometer 
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TIR 
Thermal Infrared Radiometer 
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Fig. 2 Major Parameters of ASTER Sensors 
NASA GSFC ( Goddard Space Flight Center ) under the form 
of the * activity". NASA uploads the total schedule to Terra 
under the form of command every day. 
The data acquisition request is classified to ETR (Instrument 
Team Request ), STAR ( Science Team Request ), and other 
individual DAR, totally called xAR, and they are stored in the 
xAR Data Base, which is referenced by the “Scheduler” when 
ODS is generated. For the detail of the xAR, please refer to 
Yamaguchi, et.al, 1995. 
Resulting scene number of daily data acquisition is shown in 
the figure 3, which shows that the data acquisition of ASTER is 
very stable and can be approximated as 600 scenes per day in 
most of the operation, but is slightly decreased to about 500 
scenes per day, recently. The expected rate of data acquisition 
derived from the duty cycle was 780 scenes per day in design 
phase. But, considering the land area of the world, these 
statistics seem to be reasonable. The reason of the slight 
decrease of the data acquisition rate from 600 scenes per day to 
500 is partly because of the damage in on board SSR ( Solid 
State Recorder ), and also partly because the target area has 
become scattered, resulting in the inefficiency of the data 
acquisition. 
One challenging operation flow of the ASTER mission 
Acquired Scenes 
  
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Fig3 Number of acquired ASTER scenes per day 
operation is that the xAR is scheduled, referring to the 
successful ( cloud-free ) data acquisition, i.c. if the acquired 
data is cloud-free, ASTER will not try for this area, but if not, 
ASTER will try again for this area. For this detail, please refer 
to Miura, A. 2002. 
Another challenging operation flow is to reflect weather 
forecast information to make the ODS. By taking into account 
weather forecast information, the cloud coverage is decreased 
from the 40 - 45 % to 35 %. For this detail, please refer to the 
same literature, Miura, A.,2002. 
2.2 Data Processing of ASTER Data 
As shown in the section 2.1, the data acquisition rate per day is 
about 600 scenes per day. And the data volume of one Level 0 
scene is about 100 MB. On the other hand, nominal life time of 
ASTER is 5 year. Therefore, the estimated total scene number 
is about 1.1 million, and the total volume for 5 years is about 
110 TB. Since Level 1A product is produced 
    
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Fig.4 Coverage map of cloud free ASTER Data 
for all the acquired data, estimated total number of LIA is 1.1 
Million scenes and 110 TB. As for the Level 1B product, 
corresponding estimated total number is about 275 thousand 
scenes and 27.5TB, assuming the scenes to be requested to be 
processed up to LIB is 25%! and one LIB product has 120 
MB. Actual rule for the selection of the automatic LIB 
generation is that LIB product will be generated if the cloud 
cover of a scene is below 20 96, judged by the automatic cloud 
evaluation algorithm. In addition, if there is a request to 
generate the LIB scenes, L1B data will be generated regardless 
with the cloudiness. 
Since this data volume is very large, and for the easy access to 
the archived data, automatic data storage system was 
introduced. At the first stage, a robot system called "Powder 
Horn" using 50 GB D3 cassettes was installed. But, by the 
reasons described below, it was replaced to “Peta Site System” 
using 200 GB DTF2 tape. 
On the other hand, ASTER has been operated for more than 4 
years, there is a statistics of the data acquisition, LIA/LIB 
production. The cumulative sum of L1A and LIB data are 640 
thousand ad 170 thousand scenes. The statistical values are 
slightly smaller than the expected values for both LIA and 
LIB. The major reasons for statistics for LIA are a) the tape 
read errors b) bit flip. As for the tape read errors, relatively high 
error rate had been experienced by the time of the media change 
from D3 cassettes to DTF2 tapes ( Transition from D3 cassettes 
to DTF2 were performed during 2002 October and 2004 April). 
Change of the error rate was statistically evaluated. As for the 
685 
bit flip, a automatic correction algorithm has been applied if bit 
flip occurs in a very critical portion of the data such as time tag. 
This counter measure was applied in 2002 October. The LIA 
processing error has been occurred less frequently. However, 
bit flip could occur in the science data. In such case, processing