Abstract
The language of mathematics attracted recently the attention of philosophers, historians of mathematics, and researchers in mathematics education (see Dutilh Novaes in Formal languages in logic. A philosophical and cognitive analysis. Cambridge University, Cambridge, UK, 2012, Hoyrup in The development of algebraic symbolism. College Publications, London, 2010, Kvasz in Communication in the mathematical classroom. Wydawnictwo Uniwersitetu Rzeszowskiego, Rzeszów, pp. 207–228, 2014, Lakoff and Nunez in Where mathematics comes from. Basic Books, New York, 2000, Macbeth in Realizing reason. A narrative of truth and knowing. Oxford University Press, Oxford, 2014, Serfati in La Révolution Symbolique. La Constitution De L’Ecriture Symbolique Mathematique. Editions Petra, Paris, 2005, or Sfard in Thinking as communicating. Human development, the growth of discourses, and mathematizing. Cambridge University Press, Cambridge, UK, 2008). There exist a considerable number of approaches, each of which studies one particular aspect of the language of mathematics that is relevant in the particular context. Nevertheless, what is lacking is a theoretical framework that would make it possible to integrate these different approaches to the study of the language of mathematics and use their potential for a deeper theoretical foundation of mathematics education. The aim of the present paper is to argue for the need and to outline the possible structure of an integrative theoretical framework for the study of the language of mathematics. The author is convinced that such an integrative initiative can arise from the philosophy of mathematics that is historically grounded and educationally motivated.
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References
Crowe, M. (1975). Ten ‘laws’ concerning patterns of change in the history of mathematics. Historia Mathematica, 2, 161–166.
Diamond, C. (Ed.). (1975). Wittgenstein’s lectures on the foundations of mathematics Cambridge 1939. New York: Cornell University Press.
Dörfler, W. (2005). Diagrammatic thinking: Affordances and constraints. In M. Hoffmann, J. Lenhard, & F. Seeger (Eds.), Activity and sign (pp. 57–66). New York: Springer.
Dutilh Novaes, C. (2012). Formal languages in logic. A philosophical and cognitive analysis. Cambridge, UK: Cambridge University Press.
Ernest, P. (1998). Social constructivism as a philosophy of mathematics. New York: SUNY Press.
Hanna, G., Jahnke, H. N., & Pulte, H. (Eds.). (2010). Explanation and proof in mathematics. Philosophical and educational perspectives. New York: Springer.
Hoyrup, J. (2010). The development of algebraic symbolism. London: College Publications.
Kvasz, L. (2008a). Patterns of change. Linguistic innovations in the development of classical mathematics. Basel: Birkhäuser.
Kvasz, L. (2008b). Sprache und Zeichen in der Geschichte der Algebra—ein Beitrag zur Theorie der Vergegenständlichung. Journal für Mathematik-Didaktik, 29, 108–123.
Kvasz, L. (2012). Galileo, Descartes, and Newton—Founders of the language of physics. Acta Physica Slovaca, 62, 519–614.
Kvasz, L. (2014). Language in change: How we changed the language of mathematics and how the language of mathematics changed us. In M. Pytlak (Ed.), Communication in the mathematical classroom (pp. 207–228). Rzeszów: Wydawnictwo Uniwersitetu Rzeszowskiego.
Lakatos, I. (1976). Proofs and refutations. Cambridge, UK: Cambridge University Press.
Lakoff, G., & Nunez, R. (2000). Where mathematics comes from. New York: Basic Books.
Macbeth, D. (2014). Realizing reason. A narrative of truth and knowing. Oxford: Oxford University Press.
Netz, R. (1999). The shaping of deduction in greek mathematics. A study in cognitive history. Cambridge, UK: Cambridge University Press.
Peitgen, H. O., Jürgens, H., & Saupe, J. (1992). Chaos and fractals. New York: Springer.
Peitgen, H. O., & Richter, P. H. (1986). The beauty of fractals. New York: Springer.
Piaget, J., & Garcia, R. (1989). Psychogenesis and the history of science. New York: Columbia University Press.
Serfati, M. (2005). La Révolution Symbolique. La Constitution De L’Ecriture Symbolique Mathematique. Paris: Editions Petra.
Sfard, A. (2008). Thinking as communicating. Human development, the growth of discourses, and mathematizing. Cambridge, UK: Cambridge University Press.
Sfard, A., & Linchevski, L. (1994). The gains and the pitfalls of reification—The case of algebra. Educational Studies in Mathematics, 26, 191–228.
Wittgenstein, L. (1922). Tractatus logico-philosophicus. London: Routledge and Kegan Paul.
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The work on the paper was supported by the grant Progres Q 17 Teacher preparation and teaching profession in the context of science and research.
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Kvasz, L. (2018). On the Roles of Language in Mathematics Education. In: Ernest, P. (eds) The Philosophy of Mathematics Education Today. ICME-13 Monographs. Springer, Cham. https://doi.org/10.1007/978-3-319-77760-3_14
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