In: Wagner W., Székely, B. (eds.): ISPRS TC VII Symposium - 100 Years ISPRS, Vienna, Austria, July 5-7, 2010, IAPRS, Vol. XXXVIII, Part 7B
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shows stacked imagery composed by the NDVI images calculated
for four consecutive months from April to July. Analysis of the
stacked NDVI imagery clearly highlights permanent bare areas
(low NDVI values) as dark features, contrary to the forested or
vegetated agricultural areas (high NDVI values), which appear
in brighter shades of blue and yellow. After obtaining the Red
Edge NDVI images, a 5-band image containing the stacked NDVI
images for the months of April, May, June, July and September
were created in ERDAS Imagine. It was finally rescaled to the
dynamic range of the RapidEye imagery, which is 12 bit.
Segmentation and Classification: The 5-band stacked NDVI im
age was segmented in Definiens eCognition, using the spatial data
of the LPIS as an input thematic layer. The aim was to aggregate
into single objects, the image pixels with similar temporal be
haviour in respect to the vegetation cover. The segmentation was
performed at high detail to preserve features up to 0.1 ha within
the imagery; as a consequence the land cover features larger than
the minimum mapping unit, were over-segmented (Figure 3).
Figure 3: An extracted part from the original stacked NDVI im
agery and its segmentation by Definiens eCognition.
The spatial and alphanumeric data from the LPIS plays an inte
gral role in the segmentation and classification of the RapidEye
imagery. As a consequence, the resulting land cover segments
were coherent with the spatial extent and design of the reference
parcels of the LPIS. In addition, valuable information regarding
the type of the land use and the farmer restrictions at reference
parcel level (stored in the LPIS attribute data), was used in the
subsequent classification and aggregation of the image segments
into meaningful land cover features at a higher object level.
The resulting segments were further classified in eCognition, to
extract various land cover features. Different variables, such as
Brightness, Mean value of Red, Relative Border to, Border Index
and Thematic Attribute, have been used. The exhaustive toolbox
of eCognition, together with the extensive use of abundant Rapid-
Eye and LPIS data, gave the possibility to define and extract more
land cover types thus, enrich the initial simple binary classifica
tion of vegetated and non-vegetated areas. The land cover types
were further grouped in GAC, Potential non-GAC and Non GAC
categories, based of the pre-defined rules.
6 PRELIMINARY RESULTS
The first results obtained for the test area of KARD (Figures 4.c
and 4.d) indicate that non-GAC features can be detected with high
success rate. The overall thematic accuracy of the land cover
classification is about 81% (See Table 2). The major confusion,
which was between natural bare areas and urban areas, was not
considered critical as both classes, eventually, are classified into
the same (non-GAC) group. For KARD zone 55.1% (10118.8 ha
out of 18361.3 ha) is in GAC, 8.8% (1614.2 ha) is in potential
non-GAC and 36.1% (6628.2 ha) is in non-GAC group.
Some mixed land cover of bare areas and natural vegetation were
incorrectly validated as agricultural areas because of the vague
ness associated with ground truth samples. Unfortunately, due
Urban
Areas
Agri
culture
Forest
Bare area
(natural)
Water
Urban areas
44
0
0
9
0
Agriculture
0
141
0
0
0
Forest
0
0
58
0
0
Bare area
0
7
0
27
5
Water
0
0
0
0
26
Other
0
37
0
10
0
Producer ace.
1.0
0.76
1.0
0.59
0.84
User ace.
0.83
1.0
1.0
0.69
1.0
Overall ace.
0.81
Table 2: Producer and user accuracies for the clusters extracted
by object oriented analysis
to the limited ground truth taken directly in the field, the valida
tion of the classification was done solely on the base of informa
tion obtained from the VHR imagery. Even though having suf
ficient spatial, spectral and radiometric resolution, the IKONOS
imagery represents only a single snapshot of the ground, a limi
tation, which cannot always ensure that the information available
on the VHR image will be sufficient for a proper interpretation
of the ground truth. A further validation of the results is planned
with more reliable ground truth data, available from the annual
field inspection done by the National Administration on selected
agriculture parcels from the test zones.
7 CONCURRENT TESTING
In addition to the object oriented analysis of stacked red edge
NDVI images, a pixel based method using automated clustering
of the Self-Organizing Maps (SOMs) (Ta§demir and Milenov,
2010) has also been utilised. This SOM based analysis has ex
ploited information in all bands, i.e., each pixel has a 20-band (5
RapidEye bands for 4 consecutive months from April to July).
SOMs are unsupervised artificial neural networks that use a self
organizing learning algorithm inspired from the neural maps on
the cerebral cortex (Kohonen, 1997). They are successfully used
in remote sensing applications due to their two main properties:
i) providing an adaptive vector quantization of the data samples
to approximate the unknown density distribution of the data; ii)
distribution of these quantization prototypes on a rigid lattice
by preserving neighborhood relations in the data space so that
high-dimensional data spaces can be visualized in lower dimen
sions (preferably 2D or 3D). Comprehensive knowledge learned
by SOMs can be used for cluster extraction and knowledge dis
covery from large data sets using interactive or automated meth
ods (Ta§demir and Merenyi, 2009, Ta§demir and Milenov, 2010).
An automated hierarchical clustering of SOMs based on detailed
local density distribution, proposed in (Ta§demir and Milenov,
2010), was used for GAC detection and extraction from the 20-
band stacked RapidEye imagery. A 50 x 50 SOM was trained
by Matlab SOMtoolbox and a cluster map, focusing on the land
cover types of permanent bare areas, water, forest and vegetated
areas, was extracted. Figure 5 shows the resulting cluster map and
compares it to the map extracted by the object oriented analysis.
SOM based approach is unable to capture spatial context such as
inland grass (for example vegetation within forest) whereas ob
ject oriented approach is unable to correctly capture small fields
due to its averaging property. Despite these minor details, the re
sulting cluster maps are quite similar in terms of GAC detection.
The SOM based clustering is advantageous because it is a faster,
semi-automated method which requires much less user interac
tion than the object oriented segmentation.
