Looking at graphs through infinitesimal microscopes, windows and telescopes

David Tall

doi:10.2307/3615886

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The differential triangle of Leibniz for a real function f is found by taking an increment dx in the variable x, finding the corresponding increment dy in y = f(x) and drawing the ‘triangle’ in Fig. 1. Here ds is the increment in the length of the graph, where

and the derivative of f is

References

1. Robinson, A., Non-standard analysis. North-Holland (1970).Google Scholar

2. Tall, D. O., Standard infinitesimal calculus using the superreal numbers. Preprint, Warwick University (1979).Google Scholar

3. Tall, D. O., Infinitesimals constructed algebraically and interpreted geometrically. Mathematical Education for Teaching (to appear, 1979).Google Scholar

4. Keisler, H. J., Foundations of infinitesimal calculus. Prindle, Weber & Schmidt (1976).Google Scholar

5. Barrow, I., Lectiones geometriae (1670), edited as Geometrical lectures by Child, J. M.. Chicago (1916).Google Scholar

6. Leibniz, G. W., Nova methodus pro maximis et minimis, itemque tangentibus, quae ne fractas nec irrationales quantitates moratur, et singulare pro illi calculi genus. Acta Eruditorum 3, 467–473 (1684).Google Scholar

7. Leibniz, G. W., De geometriae recondita et analysi indivisibilium atque infinitorum. Acta Eruditorum 5, 292–300 (1686).Google Scholar

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Schwarzenberger, R. L. E. 1980. Why calculus cannot be made easy. The Mathematical Gazette, Vol. 64, Issue. 429, p. 158.

Tall, David 1980. The notion of infinite measuring number and its relevance in the intuition of infinity. Educational Studies in Mathematics, Vol. 11, Issue. 3, p. 271.

Fisher, Dawn 1982. Extending Functions to Infinitesimals of Finite Order. The American Mathematical Monthly, Vol. 89, Issue. 7, p. 443.

Hoskins, R. F. 1982. Superreals and superfunctions. International Journal of Mathematical Education in Science and Technology, Vol. 13, Issue. 1, p. 67.

Craven, B. D. 1985. Generalized functions for applications. The Journal of the Australian Mathematical Society. Series B. Applied Mathematics, Vol. 26, Issue. 3, p. 362.

2004. Infinitesimal Methods of Mathematical Analysis. p. 252.

Cabral, T.C.B. and Baldino, R.R. 2006. Cálculo Infinitesimal para Um Curso de Engenharia. Revista de Ensino de Engenharia, Vol. 25, Issue. 1, p. 3.

Tall, David O. 2007. Developing a theory of mathematical growth. ZDM, Vol. 39, Issue. 1-2, p. 145.

Bingolbali, Erhan and Monaghan, John 2008. Concept image revisited. Educational Studies in Mathematics, Vol. 68, Issue. 1, p. 19.

Henry, Valerie 2009. An Introduction to Differentials Based on Hyperreal Numbers and Infinite Microscopes. PRIMUS, Vol. 20, Issue. 1, p. 39.

Tall, David O. 2009. Dynamic mathematics and the blending of knowledge structures in the calculus. ZDM, Vol. 41, Issue. 4, p. 481.

Bair, Jacques and Henry, Valérie 2010. Implicit Differentiation with Microscopes. The Mathematical Intelligencer, Vol. 32, Issue. 1, p. 53.

Katz, Karin Usadi and Katz, Mikhail G. 2010. Zooming in on infinitesimal 1–.9.. in a post-triumvirate era. Educational Studies in Mathematics, Vol. 74, Issue. 3, p. 259.

Katz, Karin U. and Katz, Mikhail G. 2011. Cauchy's Continuum. Perspectives on Science, Vol. 19, Issue. 4, p. 426.

Katz, Karin Usadi and Katz, Mikhail G. 2012. Stevin Numbers and Reality. Foundations of Science, Vol. 17, Issue. 2, p. 109.

Katz, Karin Usadi and Katz, Mikhail G. 2012. A Burgessian Critique of Nominalistic Tendencies in Contemporary Mathematics and its Historiography. Foundations of Science, Vol. 17, Issue. 1, p. 51.

Borovik, Alexandre and Katz, Mikhail G. 2012. Who Gave You the Cauchy–Weierstrass Tale? The Dual History of Rigorous Calculus. Foundations of Science, Vol. 17, Issue. 3, p. 245.

Katz, Mikhail G. and Sherry, David 2013. Leibniz’s Infinitesimals: Their Fictionality, Their Modern Implementations, and Their Foes from Berkeley to Russell and Beyond. Erkenntnis, Vol. 78, Issue. 3, p. 571.

Tall, David 2013. How Humans Learn to Think Mathematically.

Mikhail G. Katz and Eric Leichtnam 2013. Commuting and Noncommuting Infinitesimals. The American Mathematical Monthly, Vol. 120, Issue. 7, p. 631.

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