EXPERIMENTS WITH MULTI-FREQUENCY AND MULTI-POLARIZATION SAR DATA FOR HYDROLOGICAL
PARAMETER MODELLING
Tania Neusch, Manfred Sties
Institute for Photogrammetry and Remote Sensing
University of Karlsruhe
Englerstr. 7, D-76131 Karlsruhe
email: neusch @ipf.bau-verm.uni-karlsruhe.de
sties Q ipf.bau-verm.uni-karlsruhe.de
Commission VII, Working Group 6
KEY WORDS: SAR Imagery, Airborne Sensor, Soil Moisture, Surface Roughness, Filtering, Modeling.
ABSTRACT
The spatial variability of hydrological parameters depends on factors like landscape, topography, soil type and soil surface
properties. Many solutions of hydrological problems need area wide or spatially distributed input data on the basis of regular
or irregular grids. One method to provide such data is based on geostatistical extrapolations of point measurements. We
advocate remote sensing methods to provide such data. Microwaves have the capability to penetrate into the ground and
are sensitive to hydrological phenomena; thus, active SAR sensors are suitable for this task.
On April, 17 and 21 of 1997, the Experimental Airborne Synthetic Aperture Radar (ESAR) of DLR Oberpfaffenhofen has
acquired multi-polarization and multi-frequency radar image data in C-, L-, and P-band over a little watershed in the South
West of Germany (Weiherbachtal). At the same time, field measurements regarding surface roughness, volumetric and
gravimetric soil moisture, row directions and land cover type and densities have been made on several representative
agricultural fields, distributed in the test area of 3 km x 4 km size.
After slant-to-ground range transformation and georeferencing, the radar image data have been processed to reduce the
speckle effects, with regards to the ground truth data available. The backscatter values have then been input to empirical
inversion models for the retrieval of soil water content and surface roughness. The results produced up to now show a
rough compliance with the field observations. Future work will include model refinement regarding the relief of the test area
and a more detailed analysis of the wealth of SAR image data.
In this paper, the image processing steps will be explained, the inversion models and their properties will be discussed and
preliminary results will be shown.
INTRODUCTION
The soil water budget is one of the most important elements
of the natural annual water cycle. An important aspect of
this budget refers to the soil moisture variation, which is
hard to describe due to temporal and spatial variability of
interrelated processes such as evaporation, transpiration,
infiltration and underground water restoration. However,
the quantitative description of (at least some of) these pro-
cesses including their variabilities is required for hydrolog-
ical, climatological and geological problem solving, which
has - for a long time - been restricted to point related data
from field measurements.
Today, there are efforts to and successes in generating
area wide input data to hydrological problem solutions prof-
iting from remote sensing techniques, especially from mi-
crowave remote sensing. Active microwave sensors not
only offer weather independent soil surface imaging capa-
bilities; they also provide subsurface information where the
surface penetration extent depends on both, sensor and
surface properties.
It has been shown in extense (Ulaby et al., 1981, 1982 and
1986), that microwaves are sensitive to hydrological pa-
rameters such as vegetation coverage, relief and surface
roughness. We work on the problem of separation of these
interrelated parameters from series of radar images.
Intemational Archives of Photogrammetry and Remote Sensing. Vol. XXXII, Part 7, Budapest, 1998
1 TEST AREA AND EXPERIMENTS
In contrast to airborne sensors, spaceborne sensors oper-
ate from extremely steady and fixed orbits and time cycles
and imagine the earth - up until today - in one frequency
band, at one polarization at - usually - at moderate geo-
metrical resolution, only. Hence, we decided to hire an air-
borne SAR sensor for imaging of our test area in order to
get multi-polarization, multi-frequency radar imagery at ac-
quisition dates of our choice.
A 3km x 4km watershed of the Weiherbach (Southwest
Germany) was selected as test area, the reason being,
that since 1989 in this area, many field measurements and
hydrological experiments have been performed in the con-
text of multidisciplinary research projects. Image acquisi-
tion was realized on April, 17 and 21 of 1997 with the air-
borne sensor system E-SAR (Experimental Synthetic Aper-
ture Radar) of DLR Oberpfaffenhofen (German Center for
Air- and Space-Borne Operations). This sensor system op-
erates in the X-, C-, L- and P-band, where C-band takes
only co-polarized and L- and P-band take fully polarized
radar data.
Two imaging campaigns with a mere 4 day time delay were
launched to ensure, that variations of the soil moisture were
caused by possible precipitation only, excluding influences
of variable vegetation cover or variable soil surface rough-
ness. To enforce at least one precipitation event, a small
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