4.3. Data processing and calculations 
The reproduction of the topographic development of the site 
based on the heights of the caves (and the archaeological 
material found originally in them), the settlement and the 
terraces and the shingle bars in the nearby area, and the 
geological substance that had been discovered by natural 
scientist on the walls of the settlement at Qumran (Klein, 1982), 
in the sediments that were excavated at the site, and residues 
excavated and discovered in connection with skeletons in the 
graveyard, and found also on the scroll material deposited in the 
caves, revealed many most unusual things. Our most important 
conclusion regarding the development of Qumran was that the 
site — as we know it and understand it today — probably was the 
scene of a paleoflood ca. 33 B.C. (Klein, 1982, Lónnqvist and 
Lónnqvist, 2002) with a significant magnitude, several times 
larger than peak discharges, causing landslides and fissures in 
the ground. 
As far as the astronomy of the site is concerned, the lack of true 
east-west aspect of the Qumran settlement excluded from the 
beginning that any of the major alignments observed at Qumran 
would have anything to do with the equinoctial days. When the 
winter solstice sunrise (114°) and sunset (230°) had been 
observed, measured and documented in the field, it became 
clear that an important solar alignment might be found around 
the summer solstice for the south of east-north of west 
orientation or the 286° sight line at Qumran. Initial 
mathematical calculations predicted this. Eventually this was 
proven right by empirical observations, measurements and 
photographic documentation conducted 6 months later in 1994. 
The summer solstice sunset lined up exactly with the central 
axis of locus 77, indicating that it had a solar alignment. As the 
settlement and the cemetery brought further evidence for this, 
we conclude that they must have had a religious function in 
relation to solar cult. Computer-aided astronomical calculations 
supported our identification of the solar alignment at Qumran 
for the E-W axis or the 286? sight line, but presented also stellar 
references for the 106? direction. 
The arcs of the sun between the extreme points in the horizon 
and the solar declinations for the solstices were calculated with 
the aid of astronomical algorithms and trigonometric functions 
(Karttunen et alii, 1990; Meeus, 1991, 2002). The results of the 
calculations indicated that the Qumran main azimuths of 20? 
and 106? correspond to the direction and the rising angle of the 
very well known stars y Draconis (popularly called Eltanin) and 
B Orionis (popularly called Eltanin). The computer calculations 
showed further that the star y Draconis would have been in an 
azimuth of 20? around 800 B.C. In 160 B.C., precession would 
have moved the star a degree and half to 21.5?. The ancients 
frequently used D Orionis as it always rose from the same point 
on the horizon, and it was of great importance for several 
reasons, one of them religious. The arbitrarily chosen directions 
that we measured at Qumran may well have astronomical 
importance, as we have suggested, but due to the short space 
available, this discussion will be omitted from this paper. 
The cardinal geographical directions of the Qumran settlement 
that we measured point approximately in the direction of 
Damascus (22?) and Jerusalem (282?), both of which we know 
from the Dead Sea Scrolls were important to the community. 
However, we do not believe that a geographical explanation is 
sufficient to elucidate the precise astronomical data and the 
central planning of the settlement and the cemetery. 
International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B5. Istanbul 2004 
An inventory of plans and spatial studies of excavated 
archaeological sites in the Near East, the Eastern Mediterranean 
and North and Central America made us also realize that there 
were geographically, chronologically and archaeologically 
scattered sites, which bear remarkable parallels and solar seeing 
(Fig. 5) to the layout of the Qumran ruins. 
  
  
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Fig. 5. Solar seeing and observations at Teotihuacán, Mexico 
(T) and Khirbet Qumran (Q). Based on table of declinations and 
azimuths. Prepared by R. Anttila. Note the similarity in the solar 
seeing. Teotihuacán, Mexico, is a famous solar worship place. 
We assume that this means that there was in many cases a 
central planning where geography, astronomy and perhaps solar 
religion played an important role. This is clearly demonstrated 
by the remarkable similarities in the calculated or measured 
latitudinal and the solar seeing of the sites in our case studies 
presented in 2002 (Lónnqvist and Lónnqvist, 2002. Sec also 
Fig. 6 below), and in many cases the periodical similarity. 
Arc of Ce Sun in tlie esstern horiaon in degrees 
  
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Fig. 6. The arc of the Sun in the eastern horizon at Qumran in 
degrees. Prepared by Reino Anttila. 
  
     
    
  
    
   
     
  
  
  
   
    
   
     
    
    
   
    
    
    
     
   
   
   
   
    
   
    
   
    
     
   
   
   
   
   
    
  
  
  
  
  
  
   
   
   
   
  
    
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