ENVIRONMENTAL MONITORING IN THE HIGH ARCTIC 
USING DIFFERENT TYPES OF HIGH-RESOLUTION SATELLITE IMAGERY 
Gerhard Brandstätter 
Professor, Graz University of Technology, Austria 
Aleksey Sharov 
Associate-Professor, Moscow State University of Geodesy and Cartography, Russia 
Comission VII, Working Group 3 
KEY WORDS: Topographic Monitoring, Change Detection, Image Interpretation, Multisensor Data Fusion, Radar Interferometry 
ABSTRACT 
Several approaches to spaceborne image processing based on multisensor data fusion including 
- image differencing technique applied to multitemporal spaceborne imagery, aerial photographs and available maps; 
- . combined photogrammetric processing of KATE-200 stereoscopic photographs and precision ERS-1-SAR images; 
-  inerferometric analysis of complex satellite SAR images and joint interpretation of INSAR products and stereoscopic models; 
have been investigated and practically applied for operational monitoring of topographic-glaciological changes in the Franz Josef Land 
archipelago, Russian High Arctic. A new concept of satellite topographic monitoring in the High Arctic is offered and argued. 
1. INTRODUCTION 
The High Arctic, i.e. the northernmost circumpolar 
physiographic region of the globe poleward of latitude 75? N, 
comprises a great number of large and small islands surrounding 
the interior deep-sea Arctic Basin with drifting sea ice. 
According to UN standards nearly 500 of these deserted islands 
are regarded as part of Europe. Thus, the total area of the 
European Arctic deserts occupying the archipelagoes of 
Spitsbergen, Franz Josef Land and Novaya Zemlya can be 
approximately estimated at 125.5 thousand square kilometers, 
which accounts for about 1.296 of the land surface of the "old 
world". Its extreme geographic location, unusual natural 
conditions and minimal human impact, the attractive beauty of 
its wilderness and a number of "white spots" in Arctic 
geosciences excite great scientific and public interest in this 
region. Apart from its economic and political significance the 
European Arctic is internationally acknowledged as a uniquely 
fruitful area for conducting comprehensive environmental 
research. 
In spite of traditional public opinion on such areas as being 
"natural refrigerators" experiencing one of the slowest rates of 
changes worldwide, the majority of scientists suppose that the 
high Arctic environment is subject to rapid changes due to the 
impact of ice, wind and water. In addition, environmental 
changes are brought about by active tectonic processes, which 
are still continuing in this region and heavily influence the 
evolution of Arctic archipelagoes (Matishov 1993). Moreover, 
and in contrast to Antarctica, the High Arctic is a region where 
the consequences of global environmental changes, notably 
climatic changes, are likely to be particularly severe. Therefore, 
it is reasonable to suppose that changes in size and physical 
characteristics of the Arctic ice caps are an important mechanism 
controlling global climatic change (Diament et al. 1993). Since 
movement is an inherent quality of any glacier, time series of 
systematic observations and analyses of interrelations between 
them, i.e. long-term monitoring, are needed to determine if these 
changes are of local origin or caused by variations of global 
climate patterns. The reliable models describing the dynamics of 
Arctic landforms and indicating the origin of environmental 
changes would be of fundamental significance for both basic 
geosciences and further multidisciplinary explorations in the 
High Arctic. Modes and trends of spatial changes as well as 
features of glacial evolution also need to be known for planning 
and conducting long-term economic projects, prospecting and 
Intemational Archives of Photogrammetry and Remote Sensing. Vol. XXXII, Part 7, Budapest, 1998 
rational utilization of natural resources, environmental protection 
initiatives, appropriate administration and sustainable 
development of Arctic regions. 
Techniques making use of artificial polar-orbiting satellites and 
digital information technologies are believed to be the most 
effective tools for discovering environmental changes in remote 
and inaccessible Arctic regions (Brandstitter 1997). It should be 
stressed, however, that the use of modem developments in 
satellite remote sensing and GIS technologies for environmental 
monitoring in the extreme conditions of the High Arctic is still 
largely unexplored and, thus, is of special practical importance 
and scientific interest. 
The general idea of our work was to evaluate and utilize the full 
potential of satellite remote sensing for monitoring 
environmental changes in the European High Arctic by means of 
multisensor and multitemporal remote sensing data fusion. Main 
emphasis has been put on topographic aspects of natural 
exploration and monitoring in the High Arctic, and major 
attention is paid to the following objectives: 
I. Argumentation of the concept of satellite topographic 
monitoring in the High Arctic. 
2. Development of an efficient methodology for reliable 
topographic and topological modeling of high Arctic terrain 
on the basis of multisensor and multitemporal remote 
sensing data. 
3. Designing principles and algorithms for joint topographic- 
glaciological interpretation of spaceborne optical and radar 
images. 
4. Detection and classification of present topographic changes 
in FJL at regional and local level. 
A chapter explaining the idea of satellite topographic monitoring 
in the High Arctic precedes the description of our theoretical and 
practical investigations. 
2. GENERAL CONCEPTS OF SATELLITE 
MONITORING IN THE HIGH ARCTIC 
2.1 Background 
The dynamic environment and high rates of natural changes, the 
remoteness from economically developed regions and harsh 
environment impeding both aerial surveying and extensive field 
work are the principal causes for applying satellite monitoring in 
high Arctic areas, where natural features are predominant, 
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