Transfer principleIn model theory, a transfer principle states that all statements of some language that are true for some structure are true for another structure. One of the first examples was the Lefschetz principle, which states that any sentence in the first-order language of fields that is true for the complex numbers is also true for any algebraically closed field of characteristic 0. An incipient form of a transfer principle was described by Leibniz under the name of "the Law of Continuity".
Almost everywhereIn measure theory (a branch of mathematical analysis), a property holds almost everywhere if, in a technical sense, the set for which the property holds takes up nearly all possibilities. The notion of "almost everywhere" is a companion notion to the concept of measure zero, and is analogous to the notion of almost surely in probability theory. More specifically, a property holds almost everywhere if it holds for all elements in a set except a subset of measure zero, or equivalently, if the set of elements for which the property holds is conull.
AdégalitéL’adégalité, dans l'histoire du calcul infinitésimal, est une technique développée par Pierre de Fermat, dont il dit qu'il l'a empruntée à Diophante. L'adégalité a été interprétée par certains chercheurs comme signifiant « l'égalité approximative ». John Stillwell illustre la technique dans le cadre de différentiation de comme suit. Si nous désignons l'adégalité par , alors il est juste de dire que et donc que pour la parabole est adégal à . Cependant, n'est pas un nombre ; en fait, est le seul nombre auquel est adégal.
The AnalystThe Analyst (subtitled A Discourse Addressed to an Infidel Mathematician: Wherein It Is Examined Whether the Object, Principles, and Inferences of the Modern Analysis Are More Distinctly Conceived, or More Evidently Deduced, Than Religious Mysteries and Points of Faith) is a book by George Berkeley. It was first published in 1734, first by J. Tonson (London), then by S. Fuller (Dublin). The "infidel mathematician" is believed to have been Edmond Halley, though others have speculated Sir Isaac Newton was intended.
Valuation ringIn abstract algebra, a valuation ring is an integral domain D such that for every element x of its field of fractions F, at least one of x or x−1 belongs to D. Given a field F, if D is a subring of F such that either x or x−1 belongs to D for every nonzero x in F, then D is said to be a valuation ring for the field F or a place of F. Since F in this case is indeed the field of fractions of D, a valuation ring for a field is a valuation ring.
Non-Archimedean ordered fieldIn mathematics, a non-Archimedean ordered field is an ordered field that does not satisfy the Archimedean property. Examples are the Levi-Civita field, the hyperreal numbers, the surreal numbers, the Dehn field, and the field of rational functions with real coefficients with a suitable order. The Archimedean property is a property of certain ordered fields such as the rational numbers or the real numbers, stating that every two elements are within an integer multiple of each other.
Nombre superréelEn algèbre commutative, les corps de nombres superréels sont des extensions du corps des nombres réels plus générales que les corps de nombres hyperréels. Soient X un espace de Tychonov, C(X) l'algèbre des fonctions continues sur X à valeurs réelles et P un idéal premier de C(X). Par construction, l'anneau quotient A = C(X)/P est un anneau intègre qui est une algèbre réelle et peut être muni d'un ordre total compatible avec sa structure algébrique. F, le corps des fractions de A, est appelé corps superréel si l'inclusion de dans F est stricte.
Law of continuityThe law of continuity is a heuristic principle introduced by Gottfried Leibniz based on earlier work by Nicholas of Cusa and Johannes Kepler. It is the principle that "whatever succeeds for the finite, also succeeds for the infinite". Kepler used the law of continuity to calculate the area of the circle by representing it as an infinite-sided polygon with infinitesimal sides, and adding the areas of infinitely many triangles with infinitesimal bases.
Saturated modelIn mathematical logic, and particularly in its subfield model theory, a saturated model M is one that realizes as many complete types as may be "reasonably expected" given its size. For example, an ultrapower model of the hyperreals is -saturated, meaning that every descending nested sequence of internal sets has a nonempty intersection. Let κ be a finite or infinite cardinal number and M a model in some first-order language. Then M is called κ-saturated if for all subsets A ⊆ M of cardinality less than κ, the model M realizes all complete types over A.
Internal setIn mathematical logic, in particular in model theory and nonstandard analysis, an internal set is a set that is a member of a model. The concept of internal sets is a tool in formulating the transfer principle, which concerns the logical relation between the properties of the real numbers R, and the properties of a larger field denoted *R called the hyperreal numbers. The field *R includes, in particular, infinitesimal ("infinitely small") numbers, providing a rigorous mathematical justification for their use.
