A FRAMEWORK FOR AUTOMATIC LOW-RESOLUTION SATELLITE IMAGE 
INTERPRETATION BASED ON SPECTRAL, CONTEXTUAL 
AND MULTITEMPORAL KNOWLEDGE 
G. L. A. Mota *, K. Pakzad ", S. Muller *, M. S. P. Meirelles “°, R. Q. Feitosa **, H. L. da C. Coutinho* 
“ Dept. of Electrical Engineering, Pontifical Catholic University, Rio de Janeiro, Brazil — (guimota, raul)@ele.puc-rio.br 
° Institute of Photogrammetry and Geolnformation, University of Hannover, Germany — pakzad@ipi.uni-hannover.de 
* Institut für Theoretische Nachrichtentechnik und Informationsverarbeitung, University of Hannover, Germany — 
mueller@tnt.uni-hannover.de 
? University of the State of Rio de Janeiro, Rio de Janeiro, Brazil — maggie@eng.uerj.br 
* EMBRAPA Soils, Rio de Janeiro, Brazil — heitor@cnps.embrapa.br 
Commission IV , WG IV/7 
KEY WORDS: Environment, Agriculture, Automation, Knowledge base, Fuzzy Logic, Multitemporal 
ABSTRACT: 
This work proposes a framework for increasing the degree of automation of low-resolution satellite images interpretation procedures. 
Basically, the method starts with an image segmentation which, according to a criterion of spectral response homogeneity, outlines 
the regions to be classified. The classification procedure is aided by expert knowledge. This procedure makes use of three types of 
knowledge: spectral, which relates the homogeneous classes of spectral response to the correspondent classes of interest; contextual, 
indicating the relevant contexts for the discrimination of classes with similar spectral responses; and multitemporal reasoning, 
considering both the former classification of the region and the plausible class transitions in that particular time interval. This 
strategy takes simultaneously into account spectral, contextual and multitemporal evaluations of the region which, are combined into 
a single membership value. Each membership value corresponds to a class of interest, and the highest indicates its classification. As 
a consequence, the proposed model requires as input: satellite images of the region of interest acquired in different dates; the 
accurate classification of the former image and the previous mentioned categories of expert knowledge. The prominent points of the 
proposed methodology are: its flexible structure, which allows for straightforward application of this model to low-resolution image 
interpretation cases; and the automatic learning/calibration of the spectral levels to the current time image. Experiments were 
performed in order to evaluate the potential of the proposed framework. The images employed in the experiments are situated in the 
Taquari Watershed, more exactly, in the County of Alcinópolis that belongs to the State of Mato Grosso do Sul, Brazil. The 
experimental results indicate that the use of knowledge can contribute to the increment of the degree of automation of the 
interpretation process 
1. INTRODUCTION 
Considering forests, ecosystems, productive areas and urban 
areas, remote sensing constitutes a significant tool for the 
monitoring of large regions of the surface of the Earth. 
Namely, such technology can play an important role for the 
management of the natural resources. 
However, most software packages for remote sense data 
interpretation are based on visual analysis. Although such 
packages offer digital image processing and pattern 
recognition tools, they lack of a framework to automate the 
image interpretation procedure which could increase the 
productivity of the photo-interpreters. Additionally, despite 
software development allowing the automation of some 
tasks, high level structuring is limited. Consequently, in this 
field, the development of technology is essential. 
The other motivation for this research derives from 
economical restrictions. The cost of aerial or high resolution 
satellite images — e.g. IKONOS -, considering the huge 
dimensions of threatened ecosystems currently under 
monitoring programs in countries like Brazil (tropical 
rainforests, savanna and wetlands) monitoring, is too high. 
This constitutes an obstacle to its utilization on a routine 
basis. 
Visual (manual) interpretation and analysis dates back to the 
early beginnings of remote sensing for air photo 
interpretation. On the other hand, digital processing and 
analysis is more recent, it was brought by the advent of 
digital recording of remote sensing data and the development 
of computers. Both manual and digital techniques for 
interpretation of remote sensing data have their respective 
advantages and disadvantages. Consequently, by and large, 
the interpretation of remote sensing data encompasses a 
sequence of manual and automatic steps. Considering both 
knowledge background and additional data, in the manual 
steps, a photo-interpreter calibrates/trains the automatic 
algorithms and also solves the inconsistencies of their 
outcomes. 
In low spatial resolution satellite images, distinct land cover 
classes may produce similar spectral responses turning more 
difficult their discrimination. Nonetheless, it does not 
represent a problem to experienced human photo-interpreters 
who take advantage of supplementary information (e.g. size, 
shape and texture) as well as their knowledge background in 
order to solve contradictory interpretations. The present 
proposal considers that by explicitly modeling the experience 
of a photo-interpreter about a specific site into a knowledge- 
basis, his reasoning can be computationally reproduced. 
    
   
   
   
  
   
   
    
  
  
  
  
  
  
  
   
    
   
   
  
  
  
  
  
  
  
  
  
   
   
   
    
   
   
   
   
   
    
   
      
   
    
  
   
   
         
    
    
      
    
    
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