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International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B7. Istanbul 2004 
  
paper will report on the analysis of the suitability and 
transferability of Artificial Neural Networks (ANN), using both 
mixed and unmixed pixels, as a remote sensing algorithm for 
mapping and monitoring land cover at regional areas together 
with the high spatial resolution of multispectral Carterra'™ Geo 
[KONOS imagery. 
1.2. Artificial Neural Networks in Remote Sensing 
Artificial Neural Networks have been applied to several remote 
sensing studies often resulting in higher or equal mapping 
accuracies than achieved with traditional classification 
methodologies or mixture modelling (Benediktsson et al., 1990; 
Foody et al., 1995; Atkinson et al, 1997). An advantage of 
ANNS is the ability to generalise, and they do not require end- 
member spectras for soft classifications approaches (Lippmann, 
1987; Heppner et al., 1990; Atkinson and Tatnall, 1997; Foody 
et al, 1997). It has also been found that ANN require less 
training data than traditional remote sensing classification 
approaches, such as Maximum  Likelihood classification 
(Heppner et al., 1990). However, remote sensing applications 
of ANNs have tended to use simple data sets consisting of few 
pixels and land cover classes (Bernard, 1998). The 
generalisation ability of ANNs has been found to be limited, as 
ANNs tend to be overfitted to the training data (Wilkinson, 
1997). Additionally, the fine scale spectral variation and low 
number of pixels available for training in comparison to the 
number of pixels within the image have caused difficulties in 
applying ANN to high spatial resolution imagery. In previous 
studies, the transferability over large geographical areas has 
been found to be limited and dependent on the ability of the 
ANN to generalise (Egmont-Petersen et al., 2002). This study 
therefore aims to examine the ability of ANNs to transfer 
trained knowledge, acquired by a classifier on one area, to 
classify unseen data across large geographical areas and 
potentially multi-temporal imagery. 
2. METHODOLOGY 
2.1. Study area 
The study area was located in the Northumberland National 
Park (NNP) in Northern England (UK). The NNP is one of the 
eleven English and Welsh National Parks and is valued for its 
biodiversity and wildlife. It is covered mainly by upland 
vegetation, such as bracken, heather moorland (approximately 
20% of England’s upland vegetation resources) and blanket bog 
(approx. 18 % of England’s resource) (ERDP, 2000). These 
resources are a significant proportion of the worldwide 
resources, as almost 15% of the world’s blanket bog can be 
found in Britain (RSPB, 2000; Backshall et al., 2001). 
However, the increasing pressure of changes in the environment 
and in management practices have impacted the status, 
composition and extent of important vegetation habitats and 
resulted in significant changes in the extent of upland 
communities and their biodiversity (Tallis, 1985). The 
requirement for new monitoring and management schemes and 
the high spatial variation of upland vegetation made the NNP an 
ideal test site for this study. The specific site covered by the 
IKONOS imagery is the British Ministry of Defence’s (MoD) 
Otterburn Training Area (OTA). The Otterburn range is located 
in the centre of NNP and covers 229 square km, approximately 
20% of the Park area. 
911 
2.2. Image and ground data acquisition 
A Carterra'™ Geo IKONOS image, recorded on 2™ September 
2002, was acquired for the majority of the OTA. The image 
was georeferenced to the British National Grid (BNG) using 18 
GPS ground control points, resulting in a Root Mean Squared 
(RMS) error of 2.57 m. Corrections for relief displacement, 
caused by the altitude range of the imagery of 500 m, were also 
carried out, (Hanley and Fraser, 2001). Further details of the 
geometric and atmospheric corrections applied to the image 
may be found in (Mehner et al., 2003; Mehner et al., in press). 
Ground survey data offered the only source of providing 
information on the surface land cover distribution. Several GPS 
field campaigns using the kinematic Leica GPS 500 system 
were carried out along different transects across the imagery. 
Sample points were recorded at least every metre yielding 3D 
coordinates and the vegetation type attribute. The GPS 
coordinates were transformed to BNG and thereby referenced 
with the imagery. The number of measurements per class for 
each pixel was used as a guide to calculate the land cover 
distribution of each pixel. The number of mixed pixels applied 
were however much smaller than pure pixels, reflecting the true 
spatial variation of land cover found at the test site. 
Two transects were located within the same geographical area 
(training site), while the third transect was carried out at a site 5 
km away (remote site). Both areas are similar in terms of 
vegetation types and altitude and are relatively flat, thus the 
spectral variation due to anisotropic reflectance effects was 
minimised. Initially the ANNs were trained using data, both 
mixed and unmixed pixels, from the training site and then 
applied to the remote site to test the performance of ANNs 
when classifying unseen data of a different geographical 
location. 
2.3. Artificial Neural Network design and training 
considerations 
The ability of an ANN to classify unseen data successfully and 
thereby transfer its trained knowledge dependent on its ability to 
generalise (Haykin, 1999). The generalisation of an ANN is 
influenced by several parameters, which require an optimal 
choice. : 
2.3.1. Design The classification performance of an ANN is 
influenced by its design depending on a choice of several 
parameters, such as the number of hidden nodes and learning 
algorithms (Haykin, 1999). The most common type of ANN 
used in remote sensing is the Multilayer Perceptron (MLP), 
which was also chosen for this study (Lippmann, 1987; Lees, 
1996; Atkinson and Tatnall, 1997). MLPs have shown to be a 
suitable ANN design for many remote sensing applications 
(Lees, 1996). MLPs consist of three different kinds of layers: 
input layer, hidden layer and output layer. The number of nodes 
in the input layer is determined by the number of input bands, 
which is: four IKONOS bands - blue, green, red and near- 
infrared - as well as the Normalized Difference Vegetation 
Index (NDVI), calculated to enhance the spectral separability 
(Figure 1). The number of output nodes is dependent upon the 
number of land cover classes in the classification scheme: in 
this case eight different upland vegetation classes, such as 
Calluna vulgaris, Mire and Molinia Cearula (Figure 1) were 
considered.