Difference between revisions of "Infinitesimal"
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==Origin== | ==Origin== | ||
New Latin ''infinitesimus'' [[infinite]] in rank, from [[Latin]] ''infinitus'' | New Latin ''infinitesimus'' [[infinite]] in rank, from [[Latin]] ''infinitus'' | ||
| − | *[ | + | *[https://en.wikipedia.org/wiki/18th_century 1706] |
| − | The word infinitesimal comes from a 17th century Modern Latin coinage ''infinitesimus'', which originally referred to the "infinite-th" item in a series. It was originally introduced around 1670 by either [ | + | The word infinitesimal comes from a 17th century Modern Latin coinage ''infinitesimus'', which originally referred to the "infinite-th" item in a series. It was originally introduced around 1670 by either [https://en.wikipedia.org/wiki/Nicolaus_Mercator Nicolaus Mercator] or [https://en.wikipedia.org/wiki/Gottfried_Wilhelm_Leibniz Gottfried Wilhelm Leibniz]. |
==Definitions== | ==Definitions== | ||
*1: an infinitesimal [[quantity]] or variable | *1: an infinitesimal [[quantity]] or variable | ||
==Description== | ==Description== | ||
| − | '''Infinitesimals''' have been used to [[express]] the idea of objects so small that there is no way to see them or to [[measure]] them. The [[insight]] with exploiting infinitesimals was that objects could still retain certain defined properties, such as [[angle]] or [ | + | '''Infinitesimals''' have been used to [[express]] the idea of objects so small that there is no way to see them or to [[measure]] them. The [[insight]] with exploiting infinitesimals was that objects could still retain certain defined properties, such as [[angle]] or [https://en.wikipedia.org/wiki/Slope slope], even though these objects were quantitatively small. |
| − | In common speech, an infinitesimal object is an object which is smaller than any feasible measurement, but not zero in size; or, so small that it cannot be distinguished from zero by any available means. Hence, when used as an adjective, "infinitesimal" in the [[vernacular]] means "extremely small". An infinitesimal object by itself is often useless and not very well [[defined]]; in order to give it a [[meaning]] it usually has to be [[compared]] to another infinitesimal object in the same context (as in a derivative) or added together with an extremely large (an infinite) amount of other infinitesimal objects (as in an [ | + | In common speech, an infinitesimal object is an object which is smaller than any feasible measurement, but not zero in size; or, so small that it cannot be distinguished from zero by any available means. Hence, when used as an adjective, "infinitesimal" in the [[vernacular]] means "extremely small". An infinitesimal object by itself is often useless and not very well [[defined]]; in order to give it a [[meaning]] it usually has to be [[compared]] to another infinitesimal object in the same context (as in a derivative) or added together with an extremely large (an infinite) amount of other infinitesimal objects (as in an [https://en.wikipedia.org/wiki/Integral integral]). |
| − | [ | + | [https://en.wikipedia.org/wiki/Archimedes Archimedes] used what [[eventually]] came to be known as the [https://en.wikipedia.org/wiki/Method_of_indivisibles Method of indivisibles] in his work [https://en.wikipedia.org/wiki/The_Method_of_Mechanical_Theorems ''The Method of Mechanical Theorems''] to find areas of regions and volumes of solids. In his formal published treatises, Archimedes solved the same problem using the [https://en.wikipedia.org/wiki/Method_of_Exhaustion Method of Exhaustion]. The 15th century saw the work of [https://en.wikipedia.org/wiki/Nicholas_of_Cusa Nicholas of Cusa], further developed in the 17th century by [https://en.wikipedia.org/wiki/Johannes_Kepler Johannes Kepler], in particular calculation of area of a circle by representing the latter as an infinite-sided polygon. [https://en.wikipedia.org/wiki/Simon_Stevin Simon Stevin]'s work on decimal representation of all [[numbers]] in the 16th century prepared the ground for the real [[continuum]]. [https://en.wikipedia.org/wiki/Bonaventura_Cavalieri Bonaventura Cavalieri]'s method of indivisibles led to an extension of the results of the classical authors. The [[method]] of indivisibles related to [[geometrical]] figures as being composed of entities of codimension 1.[https://en.wikipedia.org/wiki/John_Wallis John Wallis]'s infinitesimals differed from indivisibles in that he would decompose geometrical figures into infinitely thin building blocks of the same [[dimension]] as the figure, preparing the ground for general methods of the integral calculus. He exploited an infinitesimal denoted [[File:Infinite_-_Version_2.jpg]]in area calculations. |
| − | The use of infinitesimals by [ | + | The use of infinitesimals by [https://en.wikipedia.org/wiki/Leibniz Leibniz] relied upon heuristic principles, such as the [https://en.wikipedia.org/wiki/Law_of_Continuity Law of Continuity]: what succeeds for the [[finite]] numbers succeeds also for the [[infinite]] numbers and vice versa; and the [https://en.wikipedia.org/wiki/Transcendental_Law_of_Homogeneity Transcendental Law of Homogeneity] that specifies procedures for replacing expressions involving inassignable [[quantities]], by expressions involving only assignable ones. The 18th century saw routine use of infinitesimals by mathematicians such as [https://en.wikipedia.org/wiki/Leonhard_Euler Leonhard Euler] and [https://en.wikipedia.org/wiki/Joseph_Lagrange Joseph Lagrange]. [https://en.wikipedia.org/wiki/Augustin-Louis_Cauchy Augustin-Louis Cauchy] exploited infinitesimals in defining continuity and an early form of a [https://en.wikipedia.org/wiki/Dirac_delta_function Dirac delta function]. As Cantor and Dedekind were developing more [[abstract]] versions of Stevin's continuum, [https://en.wikipedia.org/wiki/Paul_du_Bois-Reymond Paul du Bois-Reymond] wrote a series of papers on infinitesimal-enriched continua based on growth rates of functions. Du Bois-Reymond's work inspired both [https://en.wikipedia.org/wiki/%C3%89mile_Borel Émile Borel] and [https://en.wikipedia.org/wiki/Thoralf_Skolem Thoralf Skolem]. Borel explicitly linked du Bois-Reymond's work to Cauchy's work on rates of growth of infinitesimals. Skolem developed the first non-standard models of arithmetic in 1934. A mathematical implementation of both the law of continuity and infinitesimals was achieved by [https://en.wikipedia.org/wiki/Abraham_Robinson Abraham Robinson] in 1961, who developed [https://en.wikipedia.org/wiki/Non-standard_analysis non-standard analysis] based on earlier work by [https://en.wikipedia.org/wiki/Edwin_Hewitt Edwin Hewitt] in 1948 and Jerzy Łoś in 1955. The [https://en.wikipedia.org/wiki/Hyperreal_number hyperreals] implement an infinitesimal-enriched continuum and the transfer principle implements Leibniz's law of continuity. The [https://en.wikipedia.org/wiki/Standard_part_function standard part function] implements Fermat's [https://en.wikipedia.org/wiki/Adequality adequality].[https://en.wikipedia.org/wiki/Infinitesimal] |
[[Category: Mathematics]] | [[Category: Mathematics]] | ||
Latest revision as of 00:15, 13 December 2020
Origin
New Latin infinitesimus infinite in rank, from Latin infinitus
The word infinitesimal comes from a 17th century Modern Latin coinage infinitesimus, which originally referred to the "infinite-th" item in a series. It was originally introduced around 1670 by either Nicolaus Mercator or Gottfried Wilhelm Leibniz.
Definitions
- 1: an infinitesimal quantity or variable
Description
Infinitesimals have been used to express the idea of objects so small that there is no way to see them or to measure them. The insight with exploiting infinitesimals was that objects could still retain certain defined properties, such as angle or slope, even though these objects were quantitatively small.
In common speech, an infinitesimal object is an object which is smaller than any feasible measurement, but not zero in size; or, so small that it cannot be distinguished from zero by any available means. Hence, when used as an adjective, "infinitesimal" in the vernacular means "extremely small". An infinitesimal object by itself is often useless and not very well defined; in order to give it a meaning it usually has to be compared to another infinitesimal object in the same context (as in a derivative) or added together with an extremely large (an infinite) amount of other infinitesimal objects (as in an integral).
Archimedes used what eventually came to be known as the Method of indivisibles in his work The Method of Mechanical Theorems to find areas of regions and volumes of solids. In his formal published treatises, Archimedes solved the same problem using the Method of Exhaustion. The 15th century saw the work of Nicholas of Cusa, further developed in the 17th century by Johannes Kepler, in particular calculation of area of a circle by representing the latter as an infinite-sided polygon. Simon Stevin's work on decimal representation of all numbers in the 16th century prepared the ground for the real continuum. Bonaventura Cavalieri's method of indivisibles led to an extension of the results of the classical authors. The method of indivisibles related to geometrical figures as being composed of entities of codimension 1.John Wallis's infinitesimals differed from indivisibles in that he would decompose geometrical figures into infinitely thin building blocks of the same dimension as the figure, preparing the ground for general methods of the integral calculus. He exploited an infinitesimal denoted 
in area calculations.
The use of infinitesimals by Leibniz relied upon heuristic principles, such as the Law of Continuity: what succeeds for the finite numbers succeeds also for the infinite numbers and vice versa; and the Transcendental Law of Homogeneity that specifies procedures for replacing expressions involving inassignable quantities, by expressions involving only assignable ones. The 18th century saw routine use of infinitesimals by mathematicians such as Leonhard Euler and Joseph Lagrange. Augustin-Louis Cauchy exploited infinitesimals in defining continuity and an early form of a Dirac delta function. As Cantor and Dedekind were developing more abstract versions of Stevin's continuum, Paul du Bois-Reymond wrote a series of papers on infinitesimal-enriched continua based on growth rates of functions. Du Bois-Reymond's work inspired both Émile Borel and Thoralf Skolem. Borel explicitly linked du Bois-Reymond's work to Cauchy's work on rates of growth of infinitesimals. Skolem developed the first non-standard models of arithmetic in 1934. A mathematical implementation of both the law of continuity and infinitesimals was achieved by Abraham Robinson in 1961, who developed non-standard analysis based on earlier work by Edwin Hewitt in 1948 and Jerzy Łoś in 1955. The hyperreals implement an infinitesimal-enriched continuum and the transfer principle implements Leibniz's law of continuity. The standard part function implements Fermat's adequality.[1]
