[From: Scientific American Article, June 1959: by Derek J. de Solla Price]
The front dial is just clean enough to say exactly what it did. It has two scales, one of which is fixed and displays the
names of the signs of the zodiac; the other is on a movable slip ring and shows the months of the year. Both scales are carefully
marked off in degrees. The front dial fitted exactly over the main driving-wheel, which seems to have turned the pointer by
means of an eccentric drum-assembly. Clearly this dial showed the annual motion of the sun in the zodiac. By means of key
letters inscribed on the zodiac scale, corresponding to other letters on the parapegma calendar plate, it also showed the
main risings and settings of bright stars and constellations throughout the year.
The back dials are more complex and less legible. The lower one had three slip rings; the upper, four. Each had a little
subsidiary dial resembling the "seconds" dial of a watch. Each of the large dials is inscribed with lines about every six
degrees, and between the lines there are letters and numbers. On the lower dial the letters and numbers seem to record "moon,
so many hours; sun, so many hours"; we therefore suggest that this scale indicates the main lunar phenomena of phases and
times of rising and setting. On the upper dial the inscriptions are much more crowded and might well present information on
the risings and settings, stations and retrogradations of the planets known to the Greeks (Mercury, Venus, Mars, Jupiter and
Saturn).
Some of the technical details of the dials are especially interesting. The front dial provides the only known extensive
specimen from antiquity of a scientifically graduated instrument. When we measure the accuracy of the graduations under the
microscope, we find that their average error over the visible 45 degrees is about a quarter of a degree. The way in which
the error varies suggests that the arc was first geometrically divided and then subdivided by eye only. Even more important,
this dial may give a means of dating the instrument astronomically.
The slip ring is necessary because the old Egyptian calendar, having no leap years, fell into error by 1/4 day every year;
the month scale thus had to be adjusted by this amount. As they are preserved the two scales of the dial are out of phase
by 13½ degrees. Standard tables show that this amount could only occur in the year 80 B.C. and (because we do not know the
month) at all years just 120 years (i.e., 30 days divided by 1/4 day per year) before or after that date. Alternative dates
are archaeologically unlikely: 200 B.C. is too early; 40 A.D. is too late. Hence, if the slip ring has not moved from its
last position, it was set in. 80 B.C. Furthermore, if we are right in supposing that a fiducial mark near the month scale
was put there originally to provide a means of setting that scale in case of accidental movement, we can tell more. This mark
is exactly 1/2 degree away from the present position of the scale, and this implies that the mark was made two years before
the setting. Thus, although the evidence is by no means conclusive, we are led to suggest that the instrument was made about
82 B.C., used for two years (just long enough for the repairs to have been needed) and then taken onto the ship within the
next 30 years.
The fragments show that the original instrument carried at least four large areas of inscription: outside the front door,
inside the back door, on the plate between the two back dials and on the parapegma plates near the front dial. As I have noted,
there are also inscriptions around all the dials, and furthermore each part and hole would seem to have had identifying letters
so that the pieces could be put together in the correct order and position. The main inscriptions are in a sorry state and
only short snatches of them can be read. To provide an idea of their condition it need only be said that in some cases a plate
has completely disappeared, leaving behind an impression of its letters, standing up in a mirror image, in relief on the soft
corrosion products on the plate below. It is remarkable that such inscriptions can be read at all.
But even from the evidence of a few complete words one can get an idea of the subject matter. The sun is mentioned several
times, and the planet Venus once; terms are used that refer to the stations and retrogradations of planets; the ecliptic is
named. Pointers, apparently those of the dials, are mentioned. A line of one inscription significantly records "76 years,
19 years." This refers to the well-known Calippic cycle of 76 years, which is four times the Metonic cycle of 19 years, or
235 synodic (lunar) months. The next line includes the number "223," which refers to the eclipse cycle of 223 lunar months.
Putting together the information gathered so far, it seems reasonable to suppose that the whole purpose of the Antikythera
device was to mechanize just this sort of cyclical relation, which was a strong feature of ancient astronomy. Using the cycles
that have been mentioned, one could easily design gearing that would operate from one dial having a wheel that revolved annually,
and turn by this gearing a series of other wheels which would move pointers indicating the sidereal, synodic and draconitic
months. Similar cycles were known for the planetary phenomena; in fact, this type of arithmetical theory is the central theme
of Seleucid Babylonian astronomy, which was transmitted to the Hellenistic world in the last few centuries B.C. Such arithmetical
schemes are quite distinct from the geometrical theory of circles and epicycles in astronomy, which seems to have been essentially
Greek. The two types of theory were unified and brought to their peak in the second century A.D. by Claudius Ptolemy, whose
labors marked the triumph of the new mathematical attitude toward geometrical models that still characterizes physics today.
The Antikythera mechanism must therefore be an arithmetical counterpart of the much more familiar geometrical models of
the solar system which were known to Plato and Archimedes and evolved into the orrery and the planetarium. The mechanism is
like. a great astronomical clock without an escapement, or like a modern analogue computer which uses mechanical parts to
save tedious calculation. It is a pity that we have no way of knowing whether the device was turned automatically or by hand.
It might have been held in the hand and turned by a wheel at the side so that it would operate as a computer, possibly for
astrological use.
[From: Scientific American Article, June 1959: by Derek J. de Solla Price]