decade. This site is an ideal test area for land cover change 
study by using satellite remotely sensed data. 
  
    
  
Korea Peninsula 
   
Hungnam 
e 
       
   
   
Kwangju 
e Pusan 
   
  
  
  
Figure 1. The Study Area in Ansan, Korea. 
2.2 Remotely Sensed Data 
The remotely sensed data were acquired by TM on Landsat 5, 
which covers a region cross Ansan, Incheon, and Seoul, with 7 
bands by 2377 lines and 2357 samples i.e. totally 5,602,589 
points for each band. The data used in this study were cut from 
the original dataset, with 600 lines and 600 samples which 
covers the study area shown in Figure 1. Ideally, the remotely 
sensed data should be obtained from a sensor system that 
acquires data at approximately the same time of day. 
Furthermore, whenever possible it is desirable to use remotely 
sensed data acquired on anniversary dates. For the purpose of 
yearly land cover change detection, four dates of remotely 
sensed data were obtained from the years of 1985 to 1993 
(Table 1). 
Table 1. Landsat TM Data Used in This Study 
  
  
  
  
  
  
Time Number of Bands | Data Size of Each Band 
May 14, 1985 7 600 x 600 pixels 
May 20, 1987 7 600 * 600 pixels 
April 26, 1990 7 600 x 600 pixels 
May 20, 1993 7 600 x 600 pixels 
  
  
  
  
2.3 Available Conventional Data and Processing 
As a pilot study, most useful conventional materials, such as 
detailed geographic status, physical environment, land use map, 
social and economic development, ecosystem, population and 
population growth, GDP and its growth, agricultural 
production and production growth for various crops concerned, 
meteorological and hydrological data, etc., have not obtained 
yet. Only the following conventional data are available for 
Ansan area: topographic map, scale 1:250,000 of 1996; 
administrative boundary and road network map, scale 
1:500,000 of 1995. 
30 METHODOLOGY 
Numerous algorithms have been developed for change 
detection, such as change detection using write function 
memory insertion (Price et al., 1992; Jensen et al., 1993); 
multi-date composite image change detection (Fung and 
LeDrew, 1987; Eastman and Fulk, 1993); image algebra 
change detection (Green et al, 1994): univariate image . 
differencing (Weismiller et al., 1977; Williams and Stauffer, 
1978), image regression (Jenson, 1983; Singh, 1986), image 
ratioing (Howarth and Wickware, 1981), vegetation index 
differencing (Nelson, 1983), etc.; manual on-screen digitization 
of change (Light, 1993; Wang et al., 1992; Lacy, 1992); post- 
classification comparison change detection (Rutchey and 
Velcheck, 1994); knowledge-based vision systems for detecting 
change (Wang, 1993, Gong et al., 1996); multi-date change 
detection using a binary change mask applied to date 2; multi- 
date change detection using ancillary data source as data 1; 
spectral change vector analysis; and so on. 
The selection of an appropriate change detection algorithm is 
very important (Jensen, 1996). First, it will have a direct 
impact on the type of image classification to be performed (if 
any). Second, it will dictate whether important “from-to” 
information can be extracted from the imagery. Post- 
classification comparison change detection was selected to 
perform land cover change detection in this study. By using 
this method, it requires rectification and classification of each 
remotely sensed image. These two maps are then compared on 
a pixel-by-pixel basis using a change detection matrix. The 
advantage of this method include the detailed from-to 
information that can be extracted and the fact that the 
classification map for the next base year is already complete 
(Jensen, 1996). However, every error in the individual date 
classification map will also be presented in the final change 
detection map (Rutchey and Velcheck, 1994). Therefore, it is 
imperative that the individual classification maps used in the 
post-classification change detection method be as accurate as 
possible (Augenstein et al., 1991). 
To perform change detection by using post-classification 
comparison change detection method, classification algorithm 
must be developed or selected so as to create accurate 
classification maps for various years. Replacing to develop a 
new classification method and algorithm, the authors tested the 
common and reputable methods, including unsupervised and 
supervised classification methods, and selected the most 
suitable one for the study area to perform change detection. 
The algorithms include: (1) Parallelepiped (PAR), (2) 
Minimum Distance (MID), (3) Mahalanobis Distance (MAD), 
(4) Maximum Likelihood (MAL), and (S) IsoData 
unsupervised classification (ISD). 
400 Intemational Archives of Photogrammetry and Remote Sensing. Vol. XXXII, Part 7, Budapest, 1998 
  
  
  
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