JardineBorisJardineNick, âCritical editing of early-modern astronomical diagramsâ, q.v.
2.
BirchThomas, The history of the Royal Society of London (4 vols, London, 1756â57), ii, 12.
3.
GeraghtyAnthony, The architectural drawings of Sir Christopher Wren at All Souls College, Oxford: A complete catalogue (Aldershot, 2007), 253 (no. 391).
4.
BennettJim, âCosmography and the meaning of sundialsâ, forthcoming in BiagioliMarioRiskinJessica (eds), Nature engaged: Science in practice from the Renaissance to the present (New York, 2011).
5.
For work within the history of science focused on gesture, see SibumHeinz Otto, âReworking the mechanical value of heat: Instruments of precision and gestures of accuracy in early Victorian Englandâ, Studies in history and philosophy of science, xxvi (1995), 73â106, and SchafferSimon, âExperimenters' techniques, dyers' hands, and the electric planetariumâ, Isis, lxxxviii (1997), 1997â83. The classic starting point for studies of gesture, both for the history of science and more broadly within the anthropology of technology, remains Marcel Mauss, âTechniques of the bodyâ, Economy and society, ii (1973), 1973â88.
6.
For recent examples of such analyses, see KusukawaSachikoMacLeanIan (eds), Transmitting knowledge: Words, images, and instruments in early modern Europe (Oxford, 2006), particularly RemmertVolker R., ââDocet parva pictura, quod multae scripturae non dicuntâ: Frontispieces, their functions, and their audiences in seventeenth-century mathematical sciencesâ, 239â70, and PantinIsabelle, âKepler's Epitome: New images for an innovative bookâ, 217â37.
7.
RuffnerJames, âThe curved and the straight: Cometary theory from Kepler to Heveliusâ, Journal for the history of astronomy, ii (1971), 178â94; BennettJ. A., âHooke and Wren and the system of the world: Some points towards an historical accountâ, The British journal for the history of science, viii (1975), 1975â61, particularly pp. 49â60; Steven Shapin, A social history of truth: Civility and science in seventeenth-century England (Chicago, 1994), 266â91. The 1664 comet has been extensively discussed. For a general survey, see YeomansDonald K., Comets: A chronological history of observation, science, myth, and folklore (New York, 1991), chap. 4; and, for an entry to more recent work, MeinelChristoph (ed.), Grenzgänger zwischen Himmel und Erde: Kometen in der FrĂźhen Neuzeit (Regensberg, 2009), 78â90, and BoschieroLuciano, âGiovanni Borelli and the comets of 1664â65â, Journal for the history of astronomy, xl (2009), 2009â30.
8.
On this point, see also the editors' introduction to the recent special issue on the biographies of scientific images in Nuncius, xxiv (2009), 279â89, p. 284â5.
The geometrical problem is presented by Hooke as a direct quotation. Hooke breaks off his English exposition saying âthe Problem as I received it, is thisâ and then provides Wren's text in Latin; HookeRobert, Lectures and collections (London, 1678), 41. The problem is accompanied by an engraved plate with six diagrams to accommodate the different cases referred to in the text. Wren had proposed the problem to John Wallis and the latter's solution also survives; see Bennett, âHooke and Wrenâ (ref. 7), 50, n. 103.
11.
Bennett, âHooke and Wrenâ (ref. 7), 52, n. 117 presents the scheme â Or rather Hooke's version of it â As a record of the determination of the comet's path from observations. But the regular presentation in five-day intervals, starting from before observations began, shows that it operates in the opposite direction.
12.
For those not inclined to experiment, an animation of the diagram is available online at http://www.mhs.ox.ac.uk/compassandrule/kiosk/wren (accessed 29 March 2010). Note that as Wren's first diagram is viewed from the south, the third diagram has south at the top and the comet might better be described as rising towards the ecliptic.
13.
For the creation of multiple view drawings, see LefèvreWolfgang, âThe emergence of combined orthographic projectionsâ, in LefèvreWolfgang (ed.), Picturing machines, 1400â1700 (Cambridge, MA, 2004), 209â44, and for competing Renaissance interpretations of the Vitruvian prescription see also Filippo Camerota's contribution to the same volume, âRenaissance descriptive geometry: The codification of drawing methodsâ, 175â208, particularly pp. 196â7. For the interconnections of Wren's mathematical, anatomical and architectural drawings, see GerbinoAnthonyJohnstonStephen, Compass and rule: Architecture as mathematical practice in England, 1500â1750 (New Haven, 2009), where Wren's comet drawing is discussed at pp. 87â90.
14.
FaleThomas, Horologiographia (London, 1593), f. 5v.
15.
How Wren constructed his parallel lines is not entirely clear. Euclid provides a purely geometrical but laborious operation, which reappears in innumerable texts on practical geometry. Parallel rules (special-purpose mathematical instruments for just this task) are known from the sixteenth century, with the publication of Fabrizio Mordente's design in 1584; see CamerotaFilippo, Il compasso di Fabrizio Mordente: Per la storia del compasso di proporzione (Florence, 2000), 158. However, according to Maya Hambly, the instrument does not seem to have been common until the eighteenth century; see her Drawing instruments, 1580â1980 (London, 1988), 111â13. In any case, most early examples are also too small for the transfers required in a drawing the size of Wren's. Tee-squares were also not widely known and the variety of directions of Wren's lines would have rendered this technique awkward or impossible. Perhaps the most likely practical solution was to slide a square against a rule, both of them core instruments of geometrical drawing practice.
16.
For recent discussions of the term âtheoricâ, which extend it beyond the traditional astronomical realm, see BennettJim, âKnowing and doing in the sixteenth century: What were instruments for?â, The British journal for the history of science, xxxvi (2003), 129â50; JohnstonStephen, âTheory, theoric, practice: Mathematics and magnetism in Elizabethan Englandâ, Journal de la Renaissance, ii (2004), 2004â62; and DuprĂŠSven, âVisualization in Renaissance optics: The function of geometrical diagrams and pictures in the transmission of practical knowledgeâ, in KusukawaMacLean (eds), op. cit. (ref. 6), 1â39, particularly pp. 26â33.
Wren does not seem to have been entirely persuaded by his own straight line hypothesis, and the comet's possible deviation from rectilinear motion was important in Hooke's framing of the issue of planetary motion; see Bennett, âHooke and Wrenâ (ref. 7), 52â5, 57â8.
19.
Note that Wren already had experience of the difficulties of accommodating observation and theory. He commented that it would be a hopeless task to devise a model for the form of Saturn that would account for all the published observations; see BennettJ. A., âChristopher Wren: Astronomy, architecture, and the mathematical sciencesâ, Journal for the history of astronomy, vi (1975), 149â84, p. 157. Wren clearly had an explicit sense that observations are not simply given but have to be considered and weighed, with those deemed less adequate or accurate rejected.
20.
BookerP. J., A history of engineering drawing (London, 1963), and DeforgeYves, Le graphisme technique: Son histoire et son enseignement (Seyssel, 1981). For important and more nuanced recent work on both machines and architecture, see Lefèvre (ed.), op. cit. (ref. 13).
21.
See, for example, the phenomenological approach of RosandDavid, Drawing acts: Studies in graphic expression and representation (Cambridge, 2002).
22.
BerminghamAnn, Learning to draw: Studies in the cultural history of a polite and useful art (New Haven, 2000). Bermingham's important study focuses on the emergence of drawing as an amateur artistic pursuit and, though occasionally referring to cartography and mathematics, considers science principally in relation to landscape and life studies.
23.
IngoldCompare Tim, âBeyond art and technology: The anthropology of skillâ, in SchifferMichael Brian (ed.), Anthropological perspectives on technology (Albuquerque, 2001), 17â31, and his Lines: A brief history (London, 2007), chap. 6. Drawing can be explored through reconstruction, using historical drawing instruments and materials to follow past prescriptions. For an example, see the video of architectural drawing at http://www.mhs.ox.ac.uk/compassandrule/kiosk/drawing (accessed 29 March 2010), though for practical reasons this introduces some anachronisms by using eighteenth-century instruments to illustrate Renaissance drawing practice.
