International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B7. Istanbul 2004 
  
able to produce results with high quality and 
confidence, especially when dealing with detection 
and mapping tasks down to the species level (Chen 
et al., 2003). 
the availability of hyperspectral and 
high resolution satellite data provides researchers 
an opportunity to pursue more complex analysis. 
Hyperspectral imagery consists of tens to hundreds 
of contiguous spectral bands therefore can provide 
Fortunately, 
more complete coverage of spectral information 
about targets. Previous studies have demonstrated 
the possibility to perform species- level vegetation 
classifications using hyperspectral data (Cochrance, 
2000; Laba et al, 2003; Schmidt & Skidmore, 2003). 
However, currently available hyperspectral satellite 
data have a limited ground resolution. This may 
create difficulties in producing precise mappings of 
vegetation types. On the other hand, although 
limited to single or few spectral bands, high 
resolution images provide detail spatial information 
about the target areas. Therefore, a combination of 
both types of data is likely to be an optimal 
approach to the mapping of nonnative plants. 
In consequence, this research undertakes an effort 
to develop a systematic method to identify an 
invasive plant (Leucaena  Leucocephala) in the 
Kenting National Park and vicinity of southern 
Taiwan using  hyperspectral images and high 
resolution satellite images. Verification with ground 
truth samples indicates that the developed method 
of combining high resolution and hyperspectral 
images is an effective and efficient approach to 
detect invasive plants in a large area. 
2 METHODS AND MATERIALS 
2.1 Analysis Procedure 
The method developed in this study consists of 
several analysis phases. First, candidate areas of 
interest where target plant (Leucaena Leucocephala) 
is most likely to be spotted are selected from the 
study area. The selection is done using NDVI and 
other vegetation indexing schemes from 
multispectral images or sub- images generated from 
hyperspectral images. In other words, regions with 
low possibility of vegetation distribution are filtered 
out. This is a practical necessity to reduce the data 
volume for analysis and to avoid negative impacts 
stemming from uninterested land- cover types. 
The second phase of analysis is to perform spectral 
analysis on hyperspectral images to identify 
Leucaena  Leucocephala from vegetation covered 
areas. The process begins with extracting helpful 
spectral features from training data and field- 
collected spectra of the target plant. The purpose of 
this process is to collect spectral features that are 
most helpful in discriminating Leucaena 
Leucocephala from other vegetation types. Then, a 
parallelpiped classification is applied to the 
hyperspectral images according to the selected 
features. One thing to note is that some of the 
features may be difficult, if not impossible, to obtain 
72 
from original data. Therefore, methods developed to 
identify subtle features in transformed spectral 
domains should be used to achieve better analysis 
performance. For example, the derivative spectral 
analysis (Tsai & Philpot, 1998; Tsai & Philpot, 2002) 
has been proved to be effective and efficient for this 
purpose. Also, in a previous study (Underwood et 
al.; 2003) researchers concluded that Minimum 
Noise Fraction (MNF) analysis method can usually 
produce better classification results when 
identifying specific vegetation types with 
hyperspectral imagery. Accordingly, this research 
also applies MNF transformation before 
classification process. 
The preliminary classification result is then quickly 
evaluated with known ground truth samples to 
identify regions with poor discrimination of target 
plant. In these spots, texture analysis of high 
resolution images will be used to further examine 
the canopy structures and other features in order to 
increase the accuracy of target mapping. As of the 
time this paper is being formatted, the 
computerized texture analysis for this purpose is 
still under development. Therefore, the analysis 
results of high resolution images shown in this 
paper were produced from interactive texture 
analysis by experienced human interpretors. 
2.2 Study Area 
As shown in Fig. 1, the study area of this research is 
the Kenting National Park and vicinity located in 
southern Taiwan. The park was established in 1984 
for the purpose of preserving natural resources and 
ecosystems. It covers an area of more than 33,000 
hectors of land (about 18,000 hectors) and ocean 
with diversified coastal zones, terrains, land- cover 
types and wildlife. The vegetation cover in this 
region consists of a rich and fertile variety of native 
and exotic species. 
120°45'E 
120*50'E 
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Figure 1. Study area (Kenting National Park and 
vicinity). 
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