The Mechanical Arts

doi:10.1017/CHOL9780521572446.028

27 - The Mechanical Arts

from Part III - Dividing the Study of Nature

Published online by Cambridge University Press: 28 March 2008

Jim Bennett

Edited by

Katharine Park and

Lorraine Daston

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Katharine Park: Affiliation:
Harvard University, Massachusetts
Lorraine Daston: Affiliation:
Max-Planck-Institut für Wissenschaftsgeschichte, Berlin

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In the sixteenth and seventeenth centuries, the term “mechanical” had three main senses – all interconnected and all relevant to the history of science. The traditional meaning referred to activities that were practical or manual. In the sixteenth century, the word acquired a new meaning, a revival of a classical sense, connecting it specifically to machines and their design and management. Finally, in the seventeenth century, “mechanical” came also to refer to a doctrine about the natural world. The phrase “mechanical arts” – artes mechanicae in postclassical Latin – had equivalents in a number of European languages. When linked to the first two of these senses, it referred to the skillful practice of a particular practical discipline or handicraft, including the working of machines.

The disciplinary relationships and boundaries observed in the activities and writings of contemporary practitioners of the mechanical arts confirm the relationship of machinery to a wider context of practical work. They also show the importance, increasing over the course of the sixteenth and seventeenth centuries, of bringing mathematics into the characterization of the “mechanical.” This is both because the design and management of machines came to be regarded as a mathematical art and because mathematics became engaged in a range of other practical work. It would be difficult and anachronistic, for example, to define a boundary between the mechanical arts and practical mathematics, as carried on by people we might more readily call “mathematical practitioners” than mechanicians or mechanics, as the practical mathematical disciplines, such as architecture, engineering, gunnery, and surveying (often referred to in English as “the mathematicals”), were directly concerned with machines.

Type: Chapter
Information: The Cambridge History of Science , pp. 673 - 695

DOI: https://doi.org/10.1017/CHOL9780521572446.028 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2006

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References

Apian, Peter, Folium populi (Ingolstadt, 1533).Google Scholar

Arnold Brown, Lloyd, The Story of Maps (New York: Dover, 1979).Google Scholar

Bacon, Francis, The Advancement of Learning, in The Works of Francis Bacon, ed. Montagu, Basil, 16 vols. (London: William Pickering, 1825–34), 2.Google Scholar

Bagrow, Leo, History of Cartography, revised by Skelton, R. A. (London: C. A. Watts, 1964).Google Scholar

Bedini, Silvio A., The Pulse of Time (Florence: Leo S. Olschki, 1991).Google Scholar

Bennett, Jim and Johnston, Stephen, The Geometry of War, 1500–1750 (Oxford: Museum of the History of Science, 1996).Google Scholar

Bennett, Jim, “Cosimo’s Cosmography: The Palazzo Vecchio and the History of Museums,” in Musa Musaei: Studies on Scientific Instruments and Collections in Honour of Mara Miniati, ed. Beretta, M., Galluzzi, P., and Triarico, C. (Florence: Leo S. Olschki, 2003).Google Scholar

Bennett, Jim, “Geometry and Surveying in Early-Seventeenth-Century England,” Annals of Science, 48 (1991).CrossRef Google Scholar

Bennett, Jim, “Geometry in Context in the Sixteenth Century: The View from the Museum,” Early Science and Medicine, 8 (2002).Google Scholar

Bennett, Jim, “Projection and the Ubiquitous Virtue of Geometry in the Renaissance,” in Making Space for Science: Territorial Themes in the Shaping of Knowledge, ed. Smith, C. and Agar, J. (London: Macmillan, 1998).Google Scholar

Bennett, Jim, “The Mechanics’s Philosophy and the Mechanical Philosophy,” History of Science, 24 (1986).CrossRef Google Scholar

Bennett, Jim, The Divided Circle: A History of Instruments for Astronomy, Navigation, and Surveying (Oxford: Phaidon Christie’s, 1987).Google Scholar

Borough, William, A Discours of the Variation of the Cumpas, or Magneticall Needle (London: Jhon Kyngston for Richard Ballard, 1581).Google Scholar

Bramer, Benjamin, Bericht zu Jobsten Burgi seligen geometrischen triangular Instruments (Kassel: Jacob Gentsch, 1648).Google Scholar

Davis, John, The Seamans Secrets (London: Thomas Dawson, 1595).Google Scholar

Digges, Thomas, A Geometrical Practical Treatise Named Pantometria… (London: Abell Jeffres, 1591).Google Scholar

Drake, Stillman, Galileo at Work: His Scientific Biography (New York: Dover, 1995).Google Scholar

Edgerton, Samuel Y., The Renaissance Rediscovery of Linear Perspective (New York: Basic Books, 1975).Google Scholar

Euclid, , The Elements of Geometrie of the Most Auncient Philosopher Euclide of Megara, trans Billingsley, H. (London: John Daye, 1570).Google Scholar

Frisius, Gemma, De astrolabo catholico liber (Antwerp, 1556).Google Scholar

Gabbey, Alan, “Between Ars and Philosophia naturalis: Reflections on the Historiography of Early Modern Mechanics,” in Renaissance and Revolution: Humanists, Scholars, Craftsmen, and Natural Philosophers in Early Modern Europe, ed. , Judith V. Field and , Frank A. J. L. James (Cambridge: Cambridge University Press, 1993).Google Scholar

Galilei, Galileo, Discorsi e dimostrazioni matematiche intorno à due nuoue scienze attenenti alla mecanica & i movimenti locali (Leiden: Elsevier, 1638).Google Scholar

Galilei, Galileo, Sidereus Nuncius; or, the Sidereal Messenger, trans. Helden, Albert (Chicago: University of Chicago Press, 1989).CrossRef Google Scholar

Galluzzi, Paolo, “Art and Artifice in the Depiction of Renaissance Machines,” in The Power of Images in Early Modern Science, ed. Lefèvre, Wolfgang, Renn, Jürgen, and Schoepflin, Urs (Basel: Birkhäuser, 2003).Google Scholar

Galluzzi, Paolo, Renaissance Engineers from Brunelleschi to Leonardo da Vinci (Florence: Giunti, 1996).Google Scholar

Gilbert, William, De magnete, magneticisque corporibus, et de magno magnete tellure (London: Petrus Short, 1600)Google Scholar

Gouk, Penelope, The Ivory Sundials of Nuremberg, 1500–1700 (Cambridge: Whipple Museum, 1988)Google Scholar

Gunter, Edmund, De sectore et radio (London: William Jones, 1623).Google Scholar

Harvey, P. D. A.Maps in Tudor England (Chicago: University of Chicago Press, 1993)Google Scholar

Heilbron, John L., The Sun in the Church: Cathedrals as Solar Observatories (Cambridge, Mass.: Harvard University Press, 1999).Google Scholar

Higton, H., Sundials at Greenwich (Oxford: Oxford University Press, 2002).Google Scholar

Hooke, Robert, Micrographia; or, Some Physiological Descriptions of Minute Bodies with Observations and Enquiries Thereupon (London: J. Martyn and J. Allestry, 1665).CrossRef Google Scholar

Johann, Stöffler, Elucidatio fabricae ususque astrolabii (Oppenheim: J. Köbel, 1513).Google Scholar

John Turner, Anthony, Astrolabes: Astrolabe Related Instruments (The Time Museum, vol. 1, pt. 1) (Rockford, Ill.: The Time Museum, 1985).Google Scholar

John Turner, Anthony, Early Scientific Instruments, Europe 1400–1800 (London: Sotheby’s, 1987).Google Scholar

Keller, A. G. “Renaissance Theaters of Machines,” Technology and Culture, 19 (1978).CrossRef Google Scholar

Kemp, Martin, The Science of Art (New Haven, Conn.: Yale University Press, 1990).Google Scholar

King, H. C. and Millburn, J. R., Geared to the Stars: The Evolution of Planetariums, Orreries and Astronomical Clocks (Bristol: Adam Hilger, 1978), esp. chap. 3.Google Scholar

L’Estrange Turner, Gerard, Elizabethan Instrument Makers: The Origins of the London Trade in Precision Instrument Making (Oxford: Oxford University Press, 2000).Google Scholar

Long, Pamela O., Openness, Secrecy, Authorship: Technical Arts and the Culture of Knowledge from Antiquity to the Renaissance (Baltimore: Johns Hopkins University Press, 2001).Google Scholar

Mahoney, Michael S., “The Measurement of Time and Longitude at Sea,” in Studies on Christiaan Huygens, ed. Bos, H. J. M., Rudwick, M. J. S., Snelders, H. A. M., and Visser, R. P. W. (Lisse: Swets and Zeitlinger, 1980).Google Scholar

Maurice, Klaus, “Jost Bürgi, or On Innovation,” in The Clockwork Universe: German Clocks and Automata, 1550–1650, ed. Maurice, Klaus and Otto, Mayr (New York: Neale Watson, 1980).Google Scholar

Newton, Issac, Philosophiae naturalis principia mathematica (London: Royal Society and Joseph Streater, 1687).CrossRef Google Scholar

Niccolò, Tartaglia, La nova scientia (Venice, 1537)Google Scholar

Norman, Robert, The Newe Attractive (London: Jhon Kyngston for Richard Ballard, 1581).Google Scholar

Oughtred, W., The Circles of Proportion and the Horizontal Instrument (London: Augustine Mathewes for Elias Allen, 1632).Google Scholar

Rathborne, Aaron, The Surveyor (London: W. Stansby for W. Barre, 1616).Google Scholar

Robert Boyle, Compare, Experiments, Notes &c. about the Mechanical Origine or Production of Divers Particular Qualities (London: E. Flesher for R. Davis, 1676).Google Scholar

Robert Boyle, Compare, New Experiments Physico-Mechanicall, Touching the Spring of the Air (Oxford: H. Hall for Thomas Robinson, 1660).Google Scholar

Rossi, Paolo, Philosophy, Technology, and the Arts in the Early Modern Era, trans. Attanasio, Salvator (New York: Harper and Row, 1970)Google Scholar

Shapin, Steven and Schaffer, Simon, Leviathan and the Air-Pump: Hobbes, Boyle, and the Experimental Life (Princeton, N.J.: Princeton University Press, 1985).Google Scholar

Symonds, Robert W., Thomas Tompion, His Life and Work (London: Spring Books, 1969).Google Scholar

Taylor, E. G. R.The Haven-Finding Art (London: Institute of Navigation, 1956).Google Scholar

Taylor, E. G. R.The Mathematical Practitioners of Tudor and Stuart England (Cambridge: Institute of Navigation, 1970).Google Scholar

Taylor, E. G. R.Tudor Geography, 1485–1583 (London: Methuen, 1930).Google Scholar

van Helden, Albert, “The Invention of the Telescope,” Transactions of the American Philosophical Society, 67 (1977), pt. 4.Google Scholar

Veltman, Kim H., with Keele, Kenneth D., Linear Perspective and the Visual Dimensions of Science and Art (Munich: Kunstverlag, 1986).Google Scholar

Waters, D. W.The Art of Navigation in England in Elizabethan and Early Stuart Times (London: Hollis and Carter, 1958).Google Scholar

Wright, M. “Robert Hooke’s Longitude Timekeeper,” in Robert Hooke: New Studies, ed. Hunter, Michael and Schaffer, Simon (Woodbridge: Boydell Press, 1989).Google Scholar

Yoder, J. G.Unrolling Time: Christiaan Huygens and the Mathematization of Nature (Cambridge: Cambridge University Press, 1988).Google Scholar

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27 - The Mechanical Arts

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