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International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B7. Istanbul 2004 
disturbance, distinct and clear tectonic evidence because there 
exists scare vegetation, uncovered surface, and dry atmospheric 
condition, and desolate and uninhabited around the area. For 
these potential advantages, this area has become the optimal 
region for using remote images to detect and investigate 
geological movement such as tectonics, fault, earthquake et al. 
Jianhua Li (1998) analyzed 1:100 0000 Landsat satellite images 
and recognized the Mani earthquake as active evidence of the 
Margaichace-Ruolacuo fault. On the remote sensing images, a 
series of valleys were distorted consistently along the 
Margaichace-Ruolacuo fault, evidently showing the fault 
features slipping along its trend. Around the Margaichace- 
Ruolacuo fault zone, linear fault reticule features are distinct 
and clear, evidently showing the appearance of left-lateral 
slipping movement. Measurement results have been reported 
that the maximum left-slip displacement of the first-level water 
system reaches 3500m (Li Jianhua, 1998). 
The data set related to our study area are ERS1/2 SLC SAR 
images (April 15, April 16, 1996 ERS-1 and Dec. 2, 1997 ERS- 
2) provided by European Space Agency. There are two scenes 
for each imaging date, so there are six scenes in total for data 
processing related to the study. 
3.2 Methods of Surface Deformation Mapping 
The data processing procedure of differential SAR 
interferometry can be divided into two big steps. Firstly, 
performing registration between the two focusing SAR images 
acquired before and after surface deformation, then conjugating 
to generate the prime interferogram; Secondly, from the prime 
interferogram subtracting the unprimed interferogram generated 
from SAR images acquired before surface deformation or 
simulated interferogram generated from existing DEM, thus 
surface deformation interferogram is obtained. 
The software for data processing in this study mainly related to 
using the EarthView Interferometric SAR Processor of Atlantis 
Scientific Inc. Canada. This processing software allows for the 
user feedback rectification of the parameters influencing 
resultant interferogram, and can meet the geoscientist’s need for 
various geo-applications of SAR interferometry. The epicenter 
of Mani is just located between the two scenes of ERS image 
Frame 2889 and Frame 2907. So it is required to manipulate 
two set of SAR images, and then mosaic the two resultant 
interferogram. 
The basic steps of InSAR data processing in our study can be 
presented as follows: 
(1) Using the ERS-1 image acquired on April 15, 1996 as slave 
image and the ERS-2 image acquired on April 16, 1996 as 
master image, which form a tandem pair, then extrácting the 
DEM of the study area. 
(2) Using the ERS-2 image acquired on Dec. 2, 1997 as slave 
image and the same image of April 16, 1996 as master image, 
forming primed interferogram by multiplying each complex 
pixel in master image by the complex conjugate of the matching 
pixel in the slave image. 
(3) Using the DEM generated from the first step, and the 
baseline parameters of the second processing step, generating 
the unprimed simulating interferogram. 
733 
(4) Finally, subtracting the unprimed interferogram from the 
primed interferogram, then obtaining differential deformation 
interferogram along slant range. 
There are some data processing steps that are either done 
differently here than in previous studies or should be elaborated 
upon for the sake of explaining the resolution and interpretation 
of our results. These include re-estimation of baselines from 
twenty GCPs collected from 1:10,0000 topographic map in 
order to improve the accuracy of DEM extraction (Kimura H, 
1997), and flat phase removal method. The flat earth correction 
method using the EarthView Software removes those fringes 
due to earth curvature and imaging geometry reference to sea 
level. So this method leads to evidently residual phase gradient 
on the interferogram because the average altitude of study area 
is 5000m. In order to avoid evident errors in DEM and surface 
deformation information extraction, the residual phase gradient 
must be removed (Goldstein R. M, Zebker H. A, 1988). As to 
the topographic interfergram, the flat region in study area was 
selected to estimate the residual phase gradient. After removing 
the residual phase gradient, the topographic interferogram was 
unwrapped and then derived DEM, which RMS is 18.7m with 
comparison to 1:100 000 topographic map. For the deformation 
detection interferogram, the region far away from epicenter and 
with regular fringes was selected to estimate the residual phase 
gradient and then removed, where impossibly exist surface 
displacement. 
Finally, the two resultant surface deformation detecting 
interferograms were mosaicked with the match errors within 
half of fringe (see Figure 2). From the mosaic interferogram, we 
can infer that the fringe errors of surface deformation detecting 
interferogram in this study, which derived from errors of 
topography and flat phase gradient, also lie within the level of 
accuracy. 
3.3 Deformation Differential 
Interferogram 
Analysis Based on 
The effects influencing interferometric data decorrelation, 
reported by Zebker (Zebker H. A. and Villasenor J, 1992), can 
be mainly attributed to these four factors: 1) baseline 
decorrelation; 2) additive —noise/spcekle; 3) temporal 
decorrelation for random phase component due to the 
complicated interference pattern produced by radar signal 
interaction with multiple ground scatterers within an image 
resolution element; 4) geometric decorrelation. In this study, we 
analyzed these factors related to the surface deformation 
detecting interferogram along the Margaichace-Ruolacuo fault, 
combining with the regional environmental conditions. 
The derived deformation detecting interferogram show several 
areas of fringe disturbance (Figure 2), and the areas other than 
the area around Margaichace-Ruolacuo fault mostly are 
associated with lakes. Because the lake water is characteristic of 
seasonal variation, we inferred that the fringe disturbance 
associated with lakes arca sound reasonable for lake-water 
backscattering decorrelation. This deformation could be either 
earthquake related or indicate a seasonal change of the lake- 
water between spring and summer. 
One of the most significant sources of error in InSAR 
processing is that of phase noise. Atmospheric disturbances, 
thermal noise, baseline effects on correlation cause phase noise. 
We can essentially ignore the former in this area because of the 
intense dryness of the atmosphere. The second, thermal noise, is