Hostname: page-component-586b7cd67f-rcrh6 Total loading time: 0 Render date: 2024-11-20T06:40:28.208Z Has data issue: false hasContentIssue false

The Antikythera Mechanism: The oldest mechanical universe in its scientific milieu

Published online by Cambridge University Press:  29 June 2011

Xenophon Moussas*
Affiliation:
Astrophysics Laboratory, Faculty of Physics, National and Kapodistrian University of Athens, Panepistimiopolis, GR 15783 Zographos, Athens, Greece email: [email protected]
Rights & Permissions [Opens in a new window]

Abstract

Core share and HTML view are not available for this content. However, as you have access to this content, a full PDF is available via the ‘Save PDF’ action button.

In this review the oldest known advanced astronomical instrument and dedicated analogue computer is presented, in context. The Antikythera Mechanism a mysterious device, assumed to be ahead of its time, probably made around 150 to 100 BCE, has been found in a 1st century BCE shipwreck near the island of Antikythera in a huge ship full of Greek treasures that were on their way to Rome. The Antikythera Mechanism is a clock-like device made of bronze gears, which looks much more advanced than its contemporary technological achievements. It is based on mathematics attributed to the Hipparchus and possibly carries knowledge and tradition that goes back to Archimedes, who according to ancient texts constructed several automata, including astronomical devices, a mechanical planetarium and a celestial sphere. The Antikythera Mechanism probably had a beautiful and expensive box; looking possibly like a very elaborate miniature Greek Temple, perhaps decorated with golden ornaments, of an elegant Hellenistic style, even perhaps with automatic statuettes, ‘daemons’, functioning as pointers that performed some of its operations. Made out of appropriately tailored trains of gears that enable to perform specialised calculations, the mechanism carries concentric scales and pointers, in one side showing the position of the Sun in the ecliptic and the sky, possibly giving the time, hour of the day or night, like a clock. The position of the Moon and its phase is also shown during the month. On the other side of the Mechanism, having probably the size of a box (main part 32×20×6 cm), are two large spiral scales with two pointers showing the time in two different very long calendars, the first one concerning the eclipses, and lasting 18 years 11 days and 8 hours, the Saros period, repeating the solar and lunar eclipses, and enabling their prediction, and the 19 year cycle of Meton, that is the period the Moon reappears in the same place of the sky, with the same phase. An additional four-year dial shows the year of all Greek Festivities, the so-called ‘games’ (Olympic, Pythian, Isthmian etc). Two additional dials give the Exeligmos, the 54 year and 34 day cycle, which provides a more accurate prediction of eclipses. It is possible that the Mechanism was also equipped with a planetary show display, as three of the planets and their motion (stationary points) are mentioned many times in the manual of the instrument, so it was also a planetarium. From the manual we have hints that the mechanism was probably also an observational instrument, as having instructions concerning a viewfinder and possibly how to orient the viewfinder to pass a sunbeam through it, probably measuring the altitude of the Sun. There are fragmented sentences that probably give instructions on how to move the pointers to set the position of the Sun, the Moon and the planets in their initial places in the ecliptic, on a specific day, or how to measure angular distances between two celestial bodies or their coordinates. This mechanism is definitely not the first one of its kind. The fact that it is accompanied with instructions means that the constructor had in its mind to be used by somebody else and one posits that he made at least another similar instrument.

Type
Contributed Papers
Copyright
Copyright © International Astronomical Union 2011

References

Berthelot, M. 1888, Collection des Anciens Alchimistes Grecs (Paris: Steinheil) http://www.rexresearch.com/alchemy5/berthelo.htm http://remacle.org/bloodwolf/alchimie/table.htmGoogle Scholar
Betegh, G. 2004, The Derveni Papyrus: Cosmology, Theology and Interpretation (Cambridge: Cambridge University Press)CrossRefGoogle Scholar
Bromley, A. G. 1986, Centaurus, 29, 5CrossRefGoogle Scholar
Bromley, A. G. 1990a, Horological Journal, 132, 412Google Scholar
Bromley, A. G. 1990b, Horological Journal, 133, 28Google Scholar
Bromley, A. G. 1990c, Antiquarian Horology, 18, 641Google Scholar
Chondros, T. G. 2009, in International Symposium on History of Machines and Mechanisms, Yan, H.-S. & Ceccarelli, M. (eds) (Berlin: Springer), p. 59CrossRefGoogle Scholar
Devevey, F. & Rousseau, A. 2009, in Cosmology Across Cultures ASP Conference Series, Vol. 409, Rubiño-Martín, J.A., Belmonte, J.A., Prada, F. & Alberdi, A. (eds) (San Francisco: Astronomical Society of the Pacific), p. 172Google Scholar
Laks, A. & Most, G. W. (eds) 1997, Studies on the Derveni papyrus (Oxford: Oxford University Press)CrossRefGoogle Scholar
Freeth, T., Bitsakis, Y., Moussas, X., Seiradakis, J. H., Tselikas, A., Mangou, H., Zafeiropoulou, M., Hadland, R., Bate, D., Ramsey, A., Allen, M., Crawley, A., Hockley, P., Malzbender, T., Gelb, D., Ambrisco, W., & Edmunds, M.G. 2006, Nature, 444, 587CrossRefGoogle Scholar
Freeth, T., Jones, A., Steele, J. M., & Bitsakis, Y. 2008, Nature, 454, 614CrossRefGoogle Scholar
Freeth, T. 2009, Scientific American, 301, 76CrossRefGoogle Scholar
Gibbon, E. 2009, The Decline and Fall of the Roman Empire (Cirencester: CRW Publishing)Google Scholar
Henriksson, G. 2011, in 17th annual meeting of the European Society for Astronomy in Culture, SEAC 2009 (Alexandria: Alexandria Library), in pressGoogle Scholar
Gourtsoyannis, E. 2010, Advances in Space Research, 46, 540CrossRefGoogle Scholar
Marchant, J. 2009, Decoding the Heavens: a 2,000-year-old computer and the century-long search to discover its secrets (Cambridge: Da Capo Press)Google Scholar
Malzbender, T., Gelb, D., & Wolters, H. 2001, in SIGGRAPH 2001, Computer Graphics Proceedings Annual Conference Series (New York: ACM Press) p. 519Google Scholar
Moussas, X., Seiradakis, J., Freeth, T., Edmunds, M., Bitsakis, Y., Babasides, G., Ioannidis-Vamvakas, D., Fasoulopoulos, G., Daniels, E. & Kriaris, D. 2007, in Communicating Astronomy to the Public, IAU Commission 55 conference 2007 (Athens) http://www.communicatingastronomy.org/cap2007/abstracts.htmlGoogle Scholar
Neugebauer, O. 1975, A History of Ancient Mathematical Astronomy (Berlin: Springer)CrossRefGoogle Scholar
Papathanasiou, M. K. 1978, Cosmological and Cosmogonical Notions in Greece during the 2nd millenium BCE, PhD Thesis (Athens: University of Athens)Google Scholar
Papathanassiou, M.K. 2010, Advances in Space Research, 46, 545CrossRefGoogle Scholar
Price, D.J. De Solla 1956, Horological Journal, 97, 811Google Scholar
Price, D. J. de Solla 1974, Transactions of the American Philosophical Society (New Series), 64, part 7, 1CrossRefGoogle Scholar
Rados, C. 1905, in Comptes rendus du Congrès international d'archéologie classique, Athènes, [7-13 avril (25-31 mars)] 1905 (Athènes: Impr. Hestia), p. 256Google Scholar
Rados, C. 1910, Peri ton Thesauron ton Antikytheron (Athens: N/A)Google Scholar
Rediadis, P. 1903, Der Astrolabos von Antikythera (Athens: Beck & Barth)Google Scholar
Rehm, A. 1907, Berliner Philologische Wochenschrift, 27, 467Google Scholar
Svoronos, J.N. 1903, Die Funde von Antikythera (Athens: Beck & Barth)Google Scholar
Svoronos, J.N. 1908, Das Athener Nationalmuseum (Athens: Beck & Barth)Google Scholar
Stamatis, E. 1974, The complete works of Archimedes (Athens: Technical Chamber of Greece)Google Scholar
Theofanidis, J. 1934, Praktika tes Akademias Athcnon, 9, 140Google Scholar
Wright, M. T. 2002, Horological Journal, 144, 169 and 193Google Scholar
Wright, M. T. 2003, Antiquarian Horology, 27, 270Google Scholar
Wright, M. T. 2005a, Bulletin of the Scientific Instrument Society, 85, 2Google Scholar
Wright, M. T. 2005b, Antiquarian Horology, 29, 51Google Scholar
Wright, M. T. 2005c, Bulletin of the Scientific Instrument Society, 87, 8Google Scholar
Wright, M. T. 2006a, Antiquarian Horology, 29, 319Google Scholar
Wright, M. T. 2006b, in Proceedings Second International Conference on Ancient Greek Technology (Athens: Technical Chamber of Greece), p. 49Google Scholar
Wright, M. T., Bromley, A. G., & Magkou, E. 1995, Journal of the European Study Group on Physical, Chemical and Mathematical Techniques applied to Archaeology, 45, 531Google Scholar