15 
ie Sozialwissen- 
C.H. Hull. Eine 
ersionen 8 und 
gart - New York, 
Satellitenbild 
aßstab 
lume "Hohe 
des österrei- 
gramms Hohe 
1 map enclosed, 
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9. Geologie des 
il. Abhandlun- 
r Reichsstelle 
25, Issue 1, 
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ARSS 1982, 
Anwendungen 
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Zeitschrift 
ation - The 
manual digi- 
RTO IV, Nachr. 
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on im Einzugsge- 
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Symposium on Remote Sensing for Resources Development and Environmental Management / Enschede / August 1986 
Digital processing of airborne MSS data 
for forest cover types classification 
Kuo-mu Chiao, Yeong-kuan Chen & Hann-chin Shieh 
National Taiwan University, Taipei 
ABSTRACT: The purpose of this study is to find optimal band combinations of airborne MSS data for forest cover 
types classification. An eleven-channel airborne multispectral scanner was used to collect data. Processing of 
the MSS data was achieved through the use of IDIMS. Forest cover types were interpreted with a hybrid super 
vised/unsupervised approach. Eight original bands of airborne MSS data and enhanced data such as principal 
component transformations, ratio images, spatial filtering data, resampling data and mixed bands were subjected 
to standard clustering and classification techniques. Among the numerous band combinations of MSS data, forty- 
seven best band combinations with highest values of average divergence and minimum divergence were selected, 
and classified on IDIMS by the maximum likelihood classifier. The optimal band combination for forest cover 
types classification provided the most accurate and detailed classification results while minimizing computer 
time and man-hours. Findings of this study are summarized as follows: (1) the best band combination is the 
combination which contains more bands; (2) resampling and spatial filtering techniques increase 7-10% classifi 
cation accuracy; and (3) Because of the inherent property, the principal component transformations, ratio 
images and mixed bands are insufficient to improve the classification accuracy. 
1 INTRODUCTION 
Resource surveys are carried out through the use of 
an airborne multispectral scanner rather than through 
the satellite data. The airborne multispectral 
scanner, which possesses the capabilities of fine 
resolution, narrow wavelength band and flexible 
scanning time, is more adequate on land cover types 
mapping than the Landsat system in an area with many 
vegetation types to be classified such as in Taiwan. 
The goal of this study is to find the optimal wave 
length band combination on land cover type classifi 
cation in forested area. Experiences have indicated 
that when working with many wavelength bands, maximum 
accuracy in classification can be obtained by using 
all wavelength bands available. However, this requires 
a marked increase in computer time. It is therefore 
frequently desirable to reduce computer time by 
utilizing only limited wavelength band in the classi 
fication procedure. The problem is which combination 
of wavenlength bands would be the optimum set to use 
in the classification. 
2 MATERIALS AND METHODS 
2.1 Data utilized 
The airborne multispectral scanner data used in this 
study were collected by a DS-1260 airborne MSS system 
with 11 channels in the Chi-tou tract of the Experi 
mental Forest of National Taiwan University in central 
Taiwan on November 21, 1982. A computer compatible 
tape (CCT) containing MSS data in band 4 to band 11 
was used in data processing (table 1). 
In order to produce images adequate for forest 
cover types classification, image enhancement tech 
niques were used to create image products which 
protray spectral pattern representing a variety of 
surface features and cover types. The enhanced data 
are principal component transformations, ratio images, 
spatial filtering data and resampling data. 
2.2 Processing techniques 
The image processing techniques were implemented 
Table 1. Airborne MSS spectral bands for data 
processing 
Channel 
Wavelength range (pm) 
4 
0.50-0.55 
5 
0.55-0.60 
6 
0.60-0.65 
7 
0.65-0.69 
8 
0.70-0.79 
9 
0.80-0.89 
10 
0.92-1.10 
11 
8.50-13.0 
through the use of the Interactive Digital Image 
Manipulation System (IDIMS) at National Central 
University, Chungli, Taiwan, Republic of China. 
As a first step in processing the imagery, the 
MAGNIFY, SCANFIX and REGISTER functions in IDIMS were 
used to geometrically correct the airborne MSS data. 
Transformations were completed to correct the syste 
matic and non-systematic errors such as aspect ratio 
error, tangential scale distortion, altitude varia 
tion and attitude variations. The non-systematic 
distortions are not predictable, 18 widely scattered 
ground control points were selected to determine the 
geometric transformations required to correct the 
image. 
To generate the enhanced imageries, the principal 
component transformation was first performed on the 
8 original bands data. In accomplishing this proce 
dure, function KLTRANS in IDIMS was applied. The 
principal component 1 (PCi) contributes 82.77% of 
the total variance by its eigenvalue; PC2 contributes 
12.24%; and PC3 contributes 4.61%. Together, PCi, 
PC2, and PC3 already account for 99.62% of the total 
variance of the 8 bands data. 
The second enhanced data is ratio images. By the 
function ADD, DIVIDE, POWER, SCALE, HIST0G and 
CONVERT in IDIMS, the 8 original airborne MSS .bands 
can be combined to produce several dozens band ratios. 
Among them, 8 ratios were selected for data processing 
experientially. They are MSS10/MSS8, MSS10/MSS6, 
MSS7/MSS9, MSS9-MSS6/MSS9+MSS6, MSS10/MSS5, MSS9/MSS11, 
MSS4/MSS7, and MSS5/MSS11. In these band ratios, some 
are good for vegetation classification; some eliminate