International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B2. Istanbul 2004
1 Introduction
Synthetic Aperture Radar (SAR) is an active remote sens-
ing system, operating in the microwave region of the elec-
tromagnetic spectrum. It emits a series of coherent, pulsed
electromagnetic waves from an antenna mounted on an
airborne or spaceborne vehicle, and records amplitude
and phase of backscattered signals from objects on the
ground (Hanssen 2001; Zhou et al., 2003). In this sense,
SAR systems acquire complex images. The deformation
of the ground surface, such as earthquake displacements,
land subsidence caused by groundwater, natural gas, or
oil extraction, can be quantified by comparing the phase
information of two complex SAR images of which the
first is recorded before deformation, and the second there-
after. This is done using differential SAR interferometry
(D-InSAR). D-InSAR provides a deformation image on a
pixel-by-pixel basis over an area of thousands of square
kilometers.
Traditionally, leveling is used for measuring vertical
deformation, i.e. subsidence and uplift, at a spatially dis-
crete set of locations along trajectories. It is followed by
interpolation to get a continuous two-dimensional cover-
age. The accuracy is high at measurement points, but
may be low at non-measured points. Besides, for a non-
homogeneous deformation pattern, point-wise leveling mea-
surements may not always be effective to represent defor-
mation, unless points are measured at a very high density.
So far, D-InSAR has not been as widely used as level-
ing. The main reason is that it produces noise and causes
artifacts during data acquisition and processing. Noise
is created by decorrelation between two or more images
acquired at different times, whereas spatial and temporal
variation in the atmosphere creates artifacts that are dif-
ficult to distinguish from ground deformation. For these
reasons, D-InSAR accuracy may be too low to detect
small deformations. Although error sources are inevitable
in differential SAR interferometry, their effects can be re-
duced.
Several studies show an agreement between DInSAR
measurements and leveling results in detecting land sub-
sidence (e.g., Carnec and Fabriol 1999), but both can be
ineffective if used alone. If only vertical deformation oc-
curs, à solution is to combine D-InSAR with leveling as
recommended by Van der Kooij (1995) and Van Bree et al.
(1999). As an alternative, Zhou et al. (2000) use a set of
sparsely distributed leveling measurements as the ground
truth, and fit a polynomial model to the differences be-
tween the two kinds of measurements at test points
In this study we further integrate data obtained with
InSAR and those obtained with leveling. The objective is
to correct the errors contained in D-InSAR measurements
by using measurements as the ground truth to improve
their accuracy. We propose the use of geostatistics to in-
un
tegrate leveling with D-InSAR. Geostatistics is well suited
to deal with data that are neither deterministic nor. purely
random, and show spatial correlation. The spatial corre-
lation is estimated by variograms, which in turn are used
to estimate deformation at non-measured locations (Chils
and Delfiner 1999). The proposed method is applied to
data collected in Tianjin Municipality. China. where land
subsidence occurs due to groundwater extraction.
2 Materials and Methods
2.1 Height change measurements by dif-
ferential SAR interferometry
Differential SAR interferometry creates two interferograms
(phase differences) from single look complex (SLC) SAR
images. The first interferogram results from two images
spanning a relatively long time interval. If the inter-
ferogram is used to detect land subsidence between two
image acquisitions, it contains fringes due to both topo-
graphic effects and height changes. The second interfero-
gram comes from two SAR images spanning a relatively
short time interval, say, one day, or is calculated from
an external Digital Elevation Model (DEM). and contains
topographic fringes only. By differencing the two interfer-
ograms, topographic effects are removed, and only height
change effects remain.
2.2 Integration of leveling and D-InSAR
measurements using geostatistics
Let Dhg(z) be a height change measurement obtained
with D-InSAR at a two-dimensional coordinate vector r
(the center of a pixel). Taking the different types of errors
in the measurement into account, we model DA,(x) by the
expression
Dh,(x) = Dh{x) + ms(x) + es (x) - e,(x) (1)
where Dh(x) denotes the true height change at x,
and m;(xr) and e(x) constitute the systematic distortion.
The term ms(x) models the bias mainly due to mean
atinospheric effects and possible indetermination of the
orbital parameters, e(x) is the spatially correlated error
caused by local atmospheric effects and uncertainty in
topographic correction. We assume that Cov(e(x), e(x *
h) — C(h), C.(h) being a covariance function, depend-
ing only on distance A. Systematic distortion is estimated
during post-processing, yielding an estimate for the true
height change and additive white noise after subtraction.
A calibrated raster height change map is generated on
the basis of height change measurements corrected for
systematic distortion.
n3
Internat
In s
of poin
Let Dh
then
whe
leveling
for the
mainly
height
locatior
À =
whe
part. h
tion 3 1
kth-ord
cess, an
in data
If su
are aval
their lex
tistical :
interpol
3 A
3.1 1
The pro
jin Mur
of Boha
sidence
tion. T
to 13.0C
the urb
between
erage rz
13.5 em
includin
dergrou
cmuyr- 3
stimulat
leading
To mon
ing site:
a levelir
mostly |
leveling
been co
nar coo
