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International Archives of the Photogrammetry, Remote Sensing and Spatial Information Sciences, Vol XXXV, Part B5. Istanbul 2004 
  
consult a professional mathematician, physicist and astronomer 
who would study the data from our fieldwork in order to reveal 
its possible relationship with astronomy and cosmic 
phenomena. 
4.1. Orientations 
The raw data that had been gathered with the tacheometric total 
station (EDM) and our azimuth measurements was allocated for 
further studies. Our astronomer R. Anttila simulated the sky 
over Qumran as it was between two-three millennia ago, 
starting from the Iron Age (about 800 B.C., which is assumed to 
be the earliest period of habitation at Qumran) to the 
Hellenistic-Roman period (2™ century B.C. to 1* century A.D.). 
The computer-aided sky-simulation was executed with a high- 
power computer of the Observatory and Astrophysics 
Laboratory at the University of Helsinki in 1994, which was 
equipped with a Sky Map planetary program (see Fig. 3). The 
sky-simulation program shows the planets and the star fields of 
a specific time as seen from a certain geographic location (in 
this case at Qumran) by using advanced mathematical formulas. 
The computer program calculates then the declination of star 
and thereafter the position of it, or a planet, at any point in the 
past or in the future. In practice this would mean that the 
spatially and archacologically measured and determined 
azimuths of the Qumran building structures and the tombs 
would. be related to the calculated declinations of a celestial 
object. À correspondence between the structures and the 
celestial objects would suggest intentional planning, according 
to celestial geography. 
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Figure 3. Computerized map of the sky over Qumran in the 
year 160 B.C., evening sky. Prepared by Reino Anttila. 
4.2. Empirical study 
As the sun, the planets and the stars were considered to be 
possible points of reference for the Qumran azimuths and the 
structures, it was, first of all, important to observe and compare 
the rare, the once-a-year astronomical appearances, but also the 
regular cosmic occurrences in their proper geographical, 
archaeological, architectural, topographical and spatial contexts 
at Qumran. This goal was achieved by observing the behaviour 
of the heavenly bodies, and measuring and calculating their 
azimuths (their risings and settings) in the field with optical and 
mechanical instruments, to see if there were any correspondence 
between the archaeological azimuths and measurements and the 
astronomical declinations of the celestial objects (declination 
-angular distance on the celestial sphere north or south of the 
celestial equator, measured in degrees, minutes and seconds 
along the hour circle passing through the celestial object, which 
is similar to latitude in geography). What interested us in 
particular was how the sun would behave in relation to the 
archaeological structures at Qumran. We observed therefore the 
equinox sunrises and sunsets, and the summer (see Fig. 4) and 
winter solstices during several years with the precision that 
could be achieved in the field. Control calculations were made 
later by the mathematician to verify the field observations. 
  
Figure 4. The summer solstice sunset in relation to the main 
ritual space of Qumran, Locus 77. Photo by Kenneth Lónnqvist 
1996. 
It was noted that the largest room at Qumran, locus 77, which is 
a ritual space, was oriented according to the summer solstice 
sunset (above, fig. 4). 
4.3. Geoarchaeology 
We also used recent geoarchaeological studies done in the Wadi 
Araba fault and the Dead Sea basin to enlarge our understanding 
of the topographical development of the area in antiquity. These 
geoarchaeological studies are based on surveys of Quaternary 
mapping, description of landforms, sedimentary deposits and 
soils which shed new light on the paleoenvironment and 
paleoclimate also on the area which is of interest for this paper 
(Niemi and Smith, 1999). Aerial photo analyses, studies of the 
sediments, soils, past cthnographical descriptions and 
morphology, as well as the paleoclimatological investigations 
(Watzman, 1994; Klein, 1965, 1982), strongly suggest that the 
paleoenvironment and paleoclimate at the region between 
Qumran and Masada was different in the Hellenistic and Roman 
periods from what it is today, less arid and more suitable both 
for living and agriculture. Because this has not been fully 
understood, we also believe many inadequate and even false 
conclusions regarding the use and chronology of Qumran have 
been drawn.