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The Social Foundations of Mechanistic Philosophy and Manufacture

Published online by Cambridge University Press:  26 September 2008

Abstract

Franz Borkenau's book, The Transition from Feudal to Modern Thought (Der Übergang vom feudalen zum bürgerlichen Weltbild [literally: The Transition from the Feudal to the Bourgeois World-Picture]), serves as background for Grossmann's study. The objective of this book was to trace the sociological origins of the mechanistic categories of modern thought as developed in the philosophy of Descartes and his successors. In the beginning of the seventeenth century, according to Borkenau, mechanistic thinking triumphed over medieval philosophy which emphasized qualitative, not quantitative considerations. This transition from medieval and feudal methods of thought to modern principles is the general theme of Borkenau's book, and is traced to the social changes of this time. According to this work, the essential economic change that marked the transition from medieval to modern times was the destruction of the handicraft system and the organization of labor under one roof and under one management. The roots of the change in thought are to be sought here. With the dismemberment of the handicraft system and the division of labor into relatively unskilled, uniform, and therefore comparable activities, the conception of abstract homogeneous social labor arises. The division of the labor process into simple repeated movements permits a comparison of hours of labor. Calculation with such abstract social unities, according to Borkenau, was the source from which modern mechanistic thinking in general derived its origin.

Grossmann, although he considers Borkenau's work a valuable and important contribution, does not believe that the author has achieved his purpose. First of all, he contends that the period that Borkenau describes as the period of the triumph of modern thought over medieval should not be placed at the beginning of the seventeenth century, but in the Renaissance, and that not Descartes and Hobbes but Leonardo da Vinci was the initiator of modern thought. Leonardo's theories, evolved from a study of machines, were the source of the mechanistic categories that culminated in modern thought.

If Borkenau's conception as to the historical origin of these categories is incorrect in regard to time, Grossmann claims it follows that it is incorrect also in regard to the social sources to which it is ascribed. In the beginning, the factory system did not involve a division of labor into comparable homogeneous processes, but in general only united skilled handicraftsmen under one roof. The development of machinery, not the calculation with abstract hours of labor, is the immediate source of modern scientific mechanics. This goes back to the Renaissance and has relatively little to do with the original factory system that was finally superseded by the Industrial Revolution.

While Borkenau, in tracing the social background of the thought of the period, relies chiefly on the conflicts and strife of political parties, Grossmann regards this as one element only in the formation of the general social situation, which in its entirety and in the interaction of its elements explains the development of modern thought.

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Copyright © Cambridge University Press 1987

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References

Translated from: “Die gesellschaftlichen Grundlagen der mechanistischen Philosophie und die Manufaktur,” Zeitschrift für Sozialforschung 4(2), Librairie Felix Alcan, Paris, 1935, pp. 161231. (A reprint of the issues published from 1931 to 1941, in 9 volumes, was published by Deutscher Taschenbuch Verlag, München, 1980.) Translated by Shalit, Gabriella, edited by Freudenthal, Gideon. Published here by kind permission of the Fondazione Max Horkheimer, Lugano.Google Scholar

English sources quoted by Grossmann in German translation are quoted here according to the English original; German sources are quoted, where possible, according toexisting English translations.Grossmann's notes are numbered according to the original, editor's notes are indicated by daggers and stars. Editor's additions to thetext are given in square brackets. The pagination of the original publication is given here in the margin. Changes in typeface are preserved from the original.Google Scholar

The English summary of the original publication (pp. 230–31) appears here as “The Argument”;the French summary (pp. 229–30) has been omitted.Google Scholar

Reification refers here to a Marxist concept (Versachlichung, Verdinglichung) in its interpretation by G.Lukacs. Marx uses the term explicitly in Capital, Vol.3, Chap.48, to denote the transformation of social relations into relations of man–produced things. Cf.Capilal, Vol.1, Chap.1, Sect.4.The concept became prominent in the discussion of G. Lukacs's History and Class Consciousness (1922). The fourth chapter bears the title “Reification(Verdinglichung), and the consciousness of the proletariat.”Google Scholar

For a discussion of the term, see our introduction, p. 107.Google Scholar

The German term Technik means “technology”as well as “techniques.” The difference is of import–ance for Grossmann's critique of Borkenau. The terms “technology”or “techniques”have been used according to our understanding of the argument.

The German Arbeitdenotes“work”and “labor”as well as the physical concept “work”: W = F−s Cf. pp. 170ff. (original pagination) of this paper.

1 de Vinci, Lëonard, Problëms de gëomëtrie et d'hydraulique. Machines hydrauliques. Application du principe de la vis d'Archimëde. Pompes, machines d'ëpuisement et de dragage, Paris 1901, Vols. I–III.Google Scholar

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1 Leonardo writes: “When dealing with scientific problems I first make some experiments, because I intend to pose the question according to experience, and then to prove why the bodies are compelled to act in the manner demonstrated. This is the method according to which one should proceed in all explorations of the phenomena of nature.” (Cf. Heller, August, Geschichte der Physik von Aristoteles bis auf die Neueste Zeit, Stuttgart 1882, Vol. I, p. 237Google Scholar. Lasswitz, Kurt, Geschichte der Atomistik, Hamburg 1890, Vol. II, p. 12.Google Scholar) “This clear insight,” adds Lasswitz, “into the essence of the experimental-mathematical method of natural sciences determines da Vinci's procedure and success.”

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2 Leonardo da Vinci als Ingenieur und Philosoph, Berlin 1874, p. 21; cf. p. 92. Similarly M. Herzfeld, Leonardo da Vinci, Leipzig 1904, CXIII. The influence of Italian science is demonstrable in other areas of Stevin's work as well: he introduced into Holland the Italian bookkeeping system whose beginnings in Florence go back to the book by Luca Paccioli (1494), Leonardo's friendGoogle Scholar. (Cf. Jäger, E. L., Luca Paccioli und Simon Stevin, Stuttgart, 1876.)Google Scholar

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2 Numerous texts by Leonardo, which illuminate his problematic show how theoretical mechanics tried to derive its concepts from the flight of projectiles. Just one example: “Si une bombarde avec 4 livres de poudre jette 4 livres de boulet à sa plus grande puissance, à 2 milles, de combien faut-il augmenter la charge de poudre pour qu'elle tire à 4 milles? La puissance du boulet dépend-ellc de sa vitesse initiate?” (Séailles, G., op. cit., p. 353).Google Scholar

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4 Also Tartag1ia's other work, Quesiti et Inventione diverse (1546), the first volume of which is devoted to the study of the motion of cannonballs; and this, according to the testimony of P. Duhem, had a strong influence on the development of mechanics in the sixteenth century. It was, therefore, of basic significance for the history of dynamics (Duhem, P., Les origines de la statique, Vol. I, p. 197).Google Scholar

1 “On peut restreindre beaucoup de la mesure commune et faire l'artillerie de moindre poids; chose qui rend trés grande facilité à la conduire et si espargne beaucoup à celui qui la fait forger” (Vanuccio Biringuccio, La pyrotechnie ou art du feu, X livres, 1st ed. 1540, quoted from the French edition, Paris 1556, p. 142).Google Scholar

2 Planchon, Mathieu, L'évolution du mécanisme de I'horlogerie depuis son origine. Bourges 1918, p. 4.Google Scholar

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1 Here I would briefly mention two of the most prominent planetaria of the sixteenth century: the one built in Paris in 1546–1553 by the mathematician and astronomer D'Oronce Finé, and the famous astronomical clock in the cathedral of Strasbourg, built in 1571–1574 by Conrad Dasypodius, professor of mathematics at Strasbourg University. Conradi Dasypodii, Horologii astronomici Argentorati descriptio, Argentorati 1580. Cf. P. Dubois, Horlogerie, Paris 1858, pp. 44–4

2 Libri, G., op. cit., Vol. II, p. 232.Google Scholar

3 Libri, G., op. cit., Vol. II, p. 217.Google Scholar

1 Libri, G., op. cit., Vol. II, p. 233.Google Scholar This Bolognese machine for spinning silk and cotton thread, with its several thousands of components, cogwheels, axles, etc., was famous and was still repeatedly described in the seventeenth century, e.g. by A. Alidosi, Instruttione delle cose notabili di Bologna (1621) and by J. J. Becher, Närrische Weisheit (1686).

2 Alberti, L. B., De re aedificatoria, Florence 1485 (posthumous), here quoted from the French edition: Paris 1553.Google Scholar

1 Libri, G., Loc. cit., Vol. III, p. 108.Google Scholar

2 Dasypodius, Conrad, Heron Mechanicus, seu de mechanicis artibus, Argentorati 1580, p. 2.Google Scholar

1 Seignobos, Ch., Histoire sinc`re de la nation française, Paris 1933, p. 238.Google Scholar

2 On the developments in Germany, Ranke, says: “The new churches were founded under the protection, the immediate influence, of the reigning powers. It is only natural that thus their shaping was also determined.” (Deutsche Geschichte im Zeitalter der Reformation, 5th ed., Leipzig 1873, Vol. II, p. 308).Google Scholar

1 Normand, Charles, La Bourgeoisie française au XVllème siècle, Paris 1908, p. 30.Google Scholar

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3 Loc. cit., p. 17.Google Scholar

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1 Normand, , op. cit., p. 43.Google Scholar

2 Sée, H., La France économique el sociale au XVIIIe siècle, Paris, 1933, p. 95.Google Scholar

3 Thus Diderot passes judgment on the parliaments: ‘Intolérant, bigot, stupide, conservant ses usages gothiques et vandales …, ardent à se mêler de tout, de religion, de gouvernement, de police, de finance, d'art et de sciences, et toujours brouillant tout daaprès son ignorance, son intérêt et ses préjugés’. And even more damning is Voltaire's (1774) judgment: “II était digne de notre nation de singes de regarder nos assassins comme nos protecteurs; nous sommes des mouches qui prenons le parti des araignées.” (Sée, , op. cit.)Google Scholar

1 Sée, H., op. cit., p. 96.Google Scholar

2 Sée, , op. cit., p. 96.Google Scholar