THE ROLE OF REMOTE SENSING AND GIS FOR AN OPERATIONAL STATE-WIDE 
ENVIRONMENTAL MONITORING 
Manfred Ehlers and Ulrich Rhein 
[ehlers, urhein]@ispa.uni-osnabrueck.de 
ISPA - University of Vechta, P.O. Box 1553 
D-49364 Vechta, Germany 
Intercommission IV/1 
KEY WORDS: Remote_Sensing, GIS, Fusion, Change_Detection, Classification 
ABSTRACT 
Remote sensing image analysis systems and geographic information systems (GIS) show great promise for the integration of a wide 
variety of spatial information supporting tasks such as urban and regional planning, natural resource management, agricultural 
studies and topographic or thematic mapping. Current and future remote sensing programs are based on a variety of sensors that 
will provide timely and repetitive multisensor earth observation on a global scale. GIS offer efficient tools for handling, 
manipulating, analysing and presenting spatial data that are required for sensible decision making in various areas. To combine the 
power of both spatial technologies, however, efficient synergistic processing techniques have to be developed to cope with large 
multisensor image datasets and to automatically extract information for GIS. This paper describes the role of remote sensing and 
GIS for an operational monitoring. The inspiration for this paper came from the project "Environmental Monitoring — State-wide 
Comparative Landuse Classification in Lower Saxony Focusing on Moor and Pasture Areas". Goals of this project are a continuos 
landuse/landcover analysis based on the classification of remotely-sensed imagery and a consequent change analysis of the state of 
Lower Saxony. Additional methods are being developed to make use of satellite imagery for assessing ecologic conditions of peat, 
boglands and pasture areas. Working in an integrated GIS/remote sensing environment allows taking advantage of the 
functionalities of both GIS and remote sensing image analysis techniques. 
1. INTRODUCTION 
We are modifying our environment at unprecedented rates and 
scales. We can, however, debate the specific spatial 
dimensions, rates and significance of these changes. 
Throughout history, technology has always been a key factor 
facilitating change. Today's technology can create 
environmental change at previously unknown spatial and 
temporal scales. Yet, it also offers us the ability to facilitate 
our investigations leading to a more complete understanding of 
human impact on our environment. Through appropriate use of 
technologies we can move a significant step towards an 
environmentally sound management of the Earth's natural 
resources. Planning and development can no longer take these 
natural resources for granted. We have to consider not only the 
needs of current generations but also those of future 
generations. 
Significant among these technologies are remote sensing and 
geographic information systems (GIS). Remote sensing devices 
on aeroplanes and satellites are capable of recording 
environmental information at staggering rates with significant 
economies of scale for many purposes. GIS can integrate these 
data with other spatial data (e.g. maps) and non-spatial data 
(e.g. tables or text) to facilitate new forms of analyses. It has to 
be noted, however, that these technologies are crossing the 
boundaries of many traditional disciplines, and the 
development of academic programs in "Remote Sensing and 
GIS for Environmental Monitoring and Management" poses a 
challenge to established programs [Ehlers, 1995]. 
Remote sensing technology and GIS are both tools for 
managing spatially distributed information in large quantities 
and at a variety of scales. Both provide a systemic or synthetic 
view of spatial information. Both increase the capabilities of 
human decision-makers and planners to grasp relationships at 
larger scales and in more complex settings than has hitherto 
been possible. GIS and image processing systems tend to two 
different forms of representing spatial information, i.e., vector 
and raster representation. These representations are 
characterised by different algorithms for spatial analyses, 
although the end results are, in theory, comparable [Ehlers, 
1992]. 
Section 2 gives an overview about the case study. It shows the 
main tasks of the environmental monitoring project. A review 
of imagery used is given in section 3 followed by a description 
of the ground truthing campaign and the integration of these 
data (section 4). After describing the geometric pre-processing 
in section 5, the results of the classification are presented in 
section 6. This section shows also the advantage of an 
integrated GIS/remote sensing environment. Section 7 gives a 
conclusion. 
2. THE CASE STUDY 
The "Environmental Monitoring - State-wide Comparative 
Landuse Classification in Lower Saxony Focusing on Moor and 
Pasture Areas" may serve as a convincing example of the 
operational use of integrated GIS/remote sensing technologies. 
This project is supported by Lower Saxony's Department of 
Environment and the German Space Agency (DARA) and 
started in July 1994. The overall goal of the project is to assess 
the capabilities of satellite remote sensing for the analysis of 
landuse changes, especially in moor and pasture areas. These 
areas are recognised as areas crucial to the mission of the 
Department of Environment and therefore to be placed under 
an extended level of protection. It is of critical importance, 
however, to have accurate and current information about the 
ecological and economic state of these sensitive areas. 
The Environmental Monitoring Project which is conducted 
jointly by the GIS and Remote Sensing Section of the Institute 
for Spatial Analysis and Planning in Areas of Intensive 
Agriculture (ISPA) and the Lower Saxony's Department of 
Environment, consist of the following tasks: 
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