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the current challenges is to bring the techniques to a level where
DEM generation can be performed on an operational basis. Multi
pass interferometry is affected by the atmospheric effects. Spatial
and temporal changes due to the 20% of relative humidity produce
an error of 10 cm in deformation. Moreover, for the image pairs
with inappropriate baseline the error introduced to the topographic
maps is almost 100 m.
Distinction between SAR imaging and the optical systems are
more profound than the ability of SAR to operate in conditions that
would cause optical instruments to fail. There are basic differences
in the physical principles dominating the two approaches. Optical
sensors record the intensity of radiation beamed from the sun and
reflected from the features. The intensity of the detected light
characterizes each element of the resulting image or pixel. SAR
antenna illuminates its target with coherent radiation. Since the
crests and troughs of the emitted electromagnetic wave follow a
regular sinusoidal pattern, both the intensity and the phase of
returned waves can be measured.
InSAR has some similarities to stereo-optical imaging in that two
images of the common area, viewed from different angles, are
appropriately combined to extract the topographic information.
The main difference between interferometry and stereo imaging is
the way to obtain topography from stereo-optical images. Distance
information is inherent in SAR data that enables the automatic
generation of topography through interferometry. In other words
DEMs can be generated by SAR interferometry with greater
automation and less errors than optical techniques. Moreover,
using DInSAR surface deformations can be measured accurately.
(Tarikhi, 2009)
4. USING INSAR TECHNIQUE FOR AQUATIC
BODIES; A NEW APPLICATION
InSAR techniques are developing rapidly and increasingly. Its civil
applications include oceanography (ocean waves, ocean currents,
wind, circulation, bathymetry), hydrology, (Kanevsky, 2009)
glaciology, seismology, volcanology, land subsidence and uplift
studies, change detection, coastal zones monitoring, forestry,
cartography, geology, soil science, agriculture, environmental and
hazard monitoring, and archaeology, (Henderson, et al. 1998)
while its non-civilian applications are reconnaissance, surveillance
and targeting, treaty verification and nonproliferation, navigation
and guidance, foliage and ground penetration, moving target
detection, and target detection and recognition. The domain and
extent of the applications of this technique is still rapidly
developing and expanding. In course of the years since 1994,
studies and verifications by the Microwave Remote Sensing Group
that is currently based at the Alborz Space Center (former
Mahdasht Satellite Receiving Station) of Iran’s space agency has
been carried out continuously on developing the applications of
InSAR technique leading to good and valuable achievements. The
studies include verifying and investigation of the variety of
phenomena namely Izmit quake of August 1999, Bam quake of
December 2003, L'Aquila quake of April 2009, Haiti earthquake
of January 2010 and Chile earthquake of February 2010.
4.1 Data and Methodology
In continuation ofthe exploratory work of using Synthetic
Aperture Radar Interferometry (InSAR) technique on aquatic
bodies in different locations of the above-mentioned study sites the
one-and-half-a-year project C1P.8242 under the ESA (European
Space Agency) affiliated European Space Research Institute
(ESRIN) was started in February 2011 by the Microwave Remote
International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Volume XXXIX-B7, 2012
XXII ISPRS Congress, 25 August — 01 September 2012, Melbourne, Australia
Sensing Group at the Mahdasht Satellite Receiving Station.
ESRIN has secured the needed data for the project. The
background of this study and exploratory work goes far back to
October 2010 when the author observed that using SAR
Interferometry technique for aquatic bodies with the temporal
baseline of maximum 16 seconds for image pairs could show
considerable results enabling us to estimate the stagger speed of
water bodies in coastal areas, the direction of sea surface motion in
larger extent, the change in the height of the sea surface in the
satellite sensor’s look direction and consequently the sea surface
height change trend, wave pattern and the sea surface disturbance
and whether the water motion is bulk and smooth or otherwise.
Figure 3 illustrates the idea and geometry of the coverage of two
successive SLC images. (Kanevsky, 2009)
4.1.1 Study Areas and data used: The method has been
examined for three different global areas in tropical zone, southern
and northern hemisphere. In the tropical zone we have studied 47
Envisat SLC SAR images of Haiti, Dominican Republic, North
Atlantic Ocean, Golfe de la Gonave, Caribbean Sea and Lago
Enriquillo acquired in 2010. For southern hemisphere 37 Envisat
SLC SAR images of Western Chile and South Pacific Ocean
acquired in 2010 have been examined. In the northern hemisphere
1860 Envisat SLC SAR images of Western Turkey including
Black and Mediterranean Seas coast areas and inland lakes
acquired in 2002-2010 have been studied, however empirical field
checkups is still necessary and the job will also be continued for
examining other sites around the world for which the relevant data
is available. For this application of SAR Interferometry the title of
Liqui-InSAR is proposed that refers to the use of SAR
interferometry technique for liquid bodies in general that is
distinguishable from the SAR Interferometry of solid bodies for
which the expression of Solid-InSAR is proposed and that deals
with the non-fluid features like soil, sand, vegetation, rocks,
snow and other cryo-spheric phenomena.
4.1.2 Methodology: Common image processing and
combination techniques used in SAR Interferometry as depicted in
Figure 1 was applied benefiting the IMAGINE-InSAR and IDIOT
to examine and assess the applicability of the technique for the
aquatic bodies. Successful use of SAR Interferometry technique
for aquatic bodies requires comparison of the SLC image pairs
with very short temporal baselines. For Envisat SLCI data the
temporal baseline should be ranging between 8 and 16 seconds. It
is because of the technology that is used by synthetic aperture
radar system. Normally the image acquisition period for each SLCI
is 16 seconds. During this period of time the SAR system transmits
a microwave beam in the form of a pulse towards the target and
then records the reflections bounced back. Sending pulses and
recording the corresponding reflections is repeated regularly but
because of the rotation of Earth and satellite movement on a
predefined and definite orbit the successive forwarded pulses hit
different locations on the land surface which are situated on the
strip that is satellite’s track on the land surface in the direction of
satellite movement. In practice there is a time overlap between two
successive imaging processes that leads to the overlap of the
scenes imaged successively. This overlap normally differs between
15 to 60 percent for ERS and Envisat SAR data. This short time
baseline is useful for ideally generating DEMs when it is shorter
than 10 seconds, and that the parallel component of the virtual
baseline decreases, since the parallel baseline component plays key
role in generating the interferograms. It is actually a way for
producing accurate DEMs benefiting three-pass SAR
Interferometry. However it is not as precise as the procedure used
by NASA’s Shuttle Radar Topography Mission (SRTM) which
