The International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences. Vol. XXXVII. Part Bl. Beijing 2008
resolution of 0.6 nm to enable the processing of the 5 nm and
10 nm channel bandwidths of EnMAP. This “monochromatic”
or fine spectral resolution database has to be resampled with the
EnMAP channel filter curves. The advantage of compiling a
“monochromatic” database is the possibility of quickly
resampling it with updated spectral channel filter functions
avoiding the necessity to run time-consuming radiative transfer
calculations for the solar and view geometry pertaining to the
acquired scenes.
The EnMAP image processing will be performed with the
ATCOR (atmospheric correction) code (e.g., Richter, R., 1996;
Richter, R., 1998) that accounts for flat and rugged terrain, and
includes haze/cirrus detection and removal algorithms.
Output products will be the ground reflectance cube, maps of
the aerosol optical thickness and atmospheric water vapor, and
masks of land, water, haze, cloud, and snow.
Water Applications
A different strategy is employed for water applications
exploiting the spectral properties of water, i.e. the low
reflectance at wavelengths greater than 800 nm can be used to
derive the aerosol map required for the retrieval of the map of
water leaving radiance. In case of specular reflection (so-called
“sun glint”) on water bodies, certain parts of the scene are
contaminated with the glint signal. The glint signal can be
removed to enable an evaluation of the water constituents in
these areas. A distinctive, physical feature of remote sensing of
water objects is that visible (and partial near infrared) radiation
penetrates the water body and is reflected back in the direction
of the sensor not only by the water surface, but also by deeper
water layers. In this context, the radiative transfer model for
processing of remote sensing water scenes should allow for the
coupled treatment of radiation propagation in both atmosphere
and water media.
A number of radiative transfer codes allow for a coupled
treatment of radiation propagation in atmosphere and water.
One of the most widely applied of these is the finite element
method. This method provides the possibility to obtain radiation
intensities in all polar and azimuthal directions and it
demonstrated better performance in the case with highly peaked
phase functions, which are typical in the atmosphere and natural
waters. In order to be used in an image processing system, the
radiative transfer code must be supplemented by optical models
of the atmosphere and water media. In particular, the MIP
(Modular Inversion Program) (e.g., Heege, T. et al., 2005) is
used, which combines the finite element method with the
MODTRAN4 atmospheric model and the multi-component
water model.
Output products are the water reflectance cube, water
constituents, the aerosol optical thickness map, and updates of
masks of land, water, haze and cloud.
4. VALIDATION
In addition to the usage of internal calibration sources and sun
calibration, vicarious validation is an essential part of the
validation during the whole mission time. After launch,
vicarious validation is the only possibility to verity the link
between the data acquired by the instrument and the data
measured at the Earth’s surface. A second topic is the
verification of EnMAP level 1 and EnMAP level 2b products
against reference measurements. Again vicarious validation is
essential to detect sensor malfunction, calibration, and
processing errors or insufficiencies.
In order to ensure the spectral, radiometric, and geometric
accuracy of the EnMAP level 1, 2a, 2b, and 2 products, they are
periodically validated within time series and with data from
other sources and of superior quality (i.e., data from airborne
hyperspectral instruments, spectroscopic field measurements).
Spectral/radiometric validation is conducted using repeated data
acquisitions for well characterized and temporally stable areas
and is further based on simultaneously acquired independent
reference data measured in the field or using airborne
spectrometers (e.g., Schroeder, M. et al., 2001; Teillet, P. M. et
al., 2001). The in-flight geometric validation will assess the
possible change of geometric parameters, e.g. the instrument or
pixel boresight and the band-to-band registration of the VNIR
and SWIR detector, by using ground control points and via the
channels of the radiometric overlap region of the two sensors.
These EnMAP calibration and validation activities are expected
to be open for the support of the international user community.
4.1 Spectral and Radiometric Validation
For the validation of the EnMAP level 1 at-sensor radiance
products, it is intended to use independent reference data
(acquired by airborne sensors and/or by field instruments).
These reference data sets (corrected to ground reflectances) will
then be converted to top-of-atmosphere radiance values using
atmospheric radiative transfer models. After that, the simulated
level 1 data and the acquired EnMAP level 1 data will be
analyzed, and a validation report will be written. In order to
minimize the influence of the atmosphere, the reference site
should be located in an environment with low atmospheric
water vapor and dust load. Well known examples are Railroad
Valley/Lunar Lake Playa (Nevada, USA) or Lake Frome
(Australia).
Assuming that such test areas are stable over time, some
analysis can take place without the need for field data taken
exactly during the EnMAP data acquisition. In this case
EnMAP data from two or more data acquisitions are analyzed
and compared to each other in order to detect changes in system
performance.
Also for the validation of EnMAP level 2 ground reflectance
products independent reference data (acquired by airborne
sensors or by field instruments) is required. In addition, an
independently (offline) processed ground reflectance product
will be generated using EnMAP level 1 data. After that, this
independent reference data, this independently processed
ground reflectance product, and the EnMAP level 2 product
will be analyzed, and a validation report will be generated. The
test sites for the validation of EnMAP level 2 products should
include a variety of typical atmospheric conditions. Apart from
spectral heterogeneity, there are no specific constraints on the
sites and validation campaigns can be conducted together with
other activities by DLR/GeoForschungsZentrum Potsdam like
airborne hyperspectral campaigns or field spectroscopic
measurements.
4.2 Geometric Calibration and Validation
Geometric processing of EnMAP scenes will be based on
laboratory calibration, resulting in instrument to star-sensors
