nes 
ine 
nts 
rful 
lds. 
ore 
ain 
age 
out 
ude 
| to 
and 
put 
nce 
ost 
nts 
ion 
| to 
een 
ues 
ysis 
ient 
d to 
| to 
red 
rity 
ige, 
ent 
and 
lant 
the 
ion 
ere 
ion 
the 
am? 
C 
C 
= 
  
  
  
300 m and 2500 m above sea level. The area is 
characterized by a variety of landcover types, including; 
forest areas, open areas and farmland which were suitable 
for the purpose of this study. 
  
WB. 
   
  
     
       
     
  
su Ann AL M nu La VU 1.30 000 13 OO. 340 (0K 
  
4 070 000 us 
  
  
  
4 0635 000 
  
  
4 060 000 4 060 000 m 
N 
0 1000 2000 km À 
J nap 
m 
  
  
  
  
     
330 007 735 000 TJT O00 ài 
  
| 
F5 000 i FAT OV 325 000 
  
  
  
Figure 1. Location of the study area 
3. Methodology 
Using raw bands of Landsat in the classification process is 
a widely used way of extracting vegetation maps. But the 
statistical similarities of vegetation spectral responses, 
spatial resolution of data and presence of similar species 
sometimes do not allow obtaining the desired results from 
the original bands. As a first step of the study raw bands of 
Landsat ETM belonging to Mediterranean region were 
classified. The maximum likelihood method was used to 
classify the image because, unlike the minimum distance 
and the parallelepiped classifiers, this technique takes into 
account both the spectral variability within and between 
classes (Fahsi et al,, 2000 ). 
The classification legend was determined by using the 
available data such as forest management maps and 
reconnaissance field survey results. While forming the 
training data, this legend was taken into account and eight 
different vegetation classes; Callabrian Pine, Black Pine, 
Taurus Fir, Taurus Cedar, Farmland, Sparse vegetation 
were discriminated. 
To check the accuracy of the results, ground truth data set 
with 26 reference point were determined using the 1/25 
000 scaled forest management map of the region. When 
the training set was applied on the classified image, an 
overall accuracy of 62.96% was obtained, which is not 
satisfactory for this kind of studies. 
7 BiroundTruthi 
Ground Truth Raster... 
- 
Figure 3. Error matrix of classification performed on raw 
bands. 
At this step a new method was implemented, in order to 
increase the accuracy of the result. Suitable vegetation 
indices and image components were produced by using 
205 
International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B7. Istanbul 2004 
Principal Component Analysis (PCA) which is a technique 
for removing or reducing the duplication or redundancy in 
multispectral images and for compressing all of the 
information that is contained in an original n-channel set 
of multispectral images into less than n channels or, more 
specifically, to their principal components (Ricotta ef al., 
1999). 
In this study the main inputs of the feature components are 
the indices. Two sets of indices were used; the first set 
includes the vegetation indices which directly give the 
spectral response of chlorophyll by using the ratio between 
red and NIR bands. The second set was used to remove the 
soil noise by changing slope value of red and NIR bands. 
First set of indices are most commonly used remote 
sensing tools for extracting green vegetation cover that 
employ red and near infrared vegetation such as 
Normalized Difference Vegetation Index (NDVI) (Drake 
et al., 1999). In addition to NDVI, Global Vegetation 
Index (GVI), Infrared Percentage Vegetation Index (IPVI), 
Transformed Vegetation Index (TVI), and Tasseled Cap 
Greenness Index were used. Equations of these indices are 
given in Table 1. 
  
  
  
  
  
Normalized NIR-red 
Difference NDVI- ----------- X 255 
Vegetation Index NIR+red 
: GV I--0,2848* TM1-0,2435* TM2- 
Global esee 0,5439*TM340,7243* 
TM4-40,0840* TM5-0,1800* TM7 
Greenness = -0.2848( TM 1)- 
Greenniess 0.2435(TM2)-0.5436(TM3)+ 
0.7243(TM4)+0.0840(TM5)- 
0.1800(TM7) 
Transformed TVI=100 * [((NIR - red) / (NIR + 
Vegetation Index red))/2)*0,5] 
Infrared ] 
Percentage IPVI= ---- (NDVI+1) 
Vegetation Index 2 
  
Soil Adjusted 
Vegetation Index 
#5 eio NIR-red 
Sonal SAV] = IH) 
L=0 for low NIR+red+L 
vegetation cover 
  
MSAVII = (( NIR-red) / (NIR + red 
Modified Soil +L)x(1+L) 
  
  
  
Adjusted 
sata : L= 1-( 2* slope * NDVI * WDWI) 
Vegetation Index 1 WDWI = NIR — slope * red 
MR dS MSAVD - 1/2*(Q*(NIRHD)- 
* + 2; (NIR- 1/2 
Vegetation Index 2 (NIE D-S Rr) 
  
Table 1. Indices used in this study 
Principal components of these six indices were calculated 
and the lists of image eigenvalue loadings for this 
transformation on all vegetation indices are given in 
Table 2. According to this table, correlations of PCI with 
the indices are very high except IPVI. This means PCI has 
a great amount of information of these 5 indices. To 
include the spectral information of IPVI in the analysis, 
PC2 is used because IPVI has a high loading value in this 
component. 92.27 percent of the spectral information was 
collected on the first two principal components; PCI and 
PC2 are selected as feature components of vegetation 
indices.