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Related papers: Strolling through common meadows

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Common meadows are commutative and associative algebraic structures with two operations (addition and multiplication) with additive and multiplicative identities and for which inverses are total. The inverse of zero is an error term…

Rings and Algebras · Mathematics 2024-06-10 João Dias , Bruno Dinis

An inversive meadow is a commutative ring with identity equipped with a multiplicative inverse operation made total by choosing 0 as its value at 0. Previously, inversive meadows were shortly called meadows. A divisive meadow is an…

Rings and Algebras · Mathematics 2010-11-03 J. A. Bergstra , C. A. Middelburg

We introduce the notion of Artinian meadow as an algebraic structure constructed from an Artinian ring which is also a common meadow, i.e.\ a commutative and associative structure with two operations (addition and multiplication) with…

Rings and Algebras · Mathematics 2024-07-11 João Dias , Bruno Dinis

Inversive meadows are commutative rings with a multiplicative identity element and a total multiplicative inverse operation whose value at 0 is 0. Divisive meadows are inversive meadows with the multiplicative inverse operation replaced by…

Rings and Algebras · Mathematics 2011-08-02 J. A. Bergstra , C. A. Middelburg

Common meadows are fields expanded with a total inverse function. Division by zero produces an additional value denoted with "a" that propagates through all operations of the meadow signature (this additional value can be interpreted as an…

Rings and Algebras · Mathematics 2021-03-23 Jan A. Bergstra , Alban Ponse

The rational, real and complex numbers with their standard operations, including division, are partial algebras specified by the axiomatic concept of a field. Since the class of fields cannot be defined by equations, the theory of…

Rings and Algebras · Mathematics 2009-01-08 J. A. Bergstra , Y. Hirshfeld , J. V. Tucker

Meadows are alternatives for fields with a purely equational axiomatization. At the basis of meadows lies the decision to make the multiplicative inverse operation total by imposing that the multiplicative inverse of zero is zero. Divisive…

Rings and Algebras · Mathematics 2016-06-08 J. A. Bergstra , C. A. Middelburg

A \emph{meadow} is a commutative ring with an inverse operator satisfying $0^{-1}=0$. We determine the initial algebra of the meadows of characteristic 0 and show that its word problem is decidable.

Rings and Algebras · Mathematics 2008-06-16 Inge Bethke , Piet Rodenburg

A meadow is a commutative ring with a total inverse operator satisfying 0^{-1}=0. We show that the class of finite meadows is the closure of the class of Galois fields under finite products. As a corollary, we obtain a unique representation…

Logic in Computer Science · Computer Science 2009-03-09 Inge Bethke , Piet Rodenburg , Arjen Sevenster

We bridge sheaves of rings over a topological space with common meadows (algebraic structures where the inverse for multiplication is a total operation). More specifically, we show that the subclass of pre-meadows with $\mathbf{a}$, coming…

Commutative Algebra · Mathematics 2024-10-10 João Dias , Bruno Dinis , Pedro Macias Marques

We analyse abstract data types that model numerical structures with a concept of error. Specifically, we focus on arithmetic data types that contain an error value $\bot$ whose main purpose is to always return a value for division. To rings…

Logic in Computer Science · Computer Science 2024-05-28 Jan A Bergstra , John V Tucker

We examine the consequences of having a total division operation $\frac{x}{y}$ on commutative rings. We consider two forms of binary division, one derived from a unary inverse, the other defined directly as a general operation; each are…

Logic in Computer Science · Computer Science 2024-12-25 Jan A Bergstra , John V Tucker

In the well-known construction of the field of fractions of an integral domain, division by zero is excluded. We introduce "fracpairs" as pairs subject to laws consistent with the use of the pair as a fraction, but do not exclude…

Rings and Algebras · Mathematics 2019-04-02 Jan A. Bergstra , Alban Ponse

Meadows have been proposed as alternatives for fields with a purely equational axiomatization. At the basis of meadows lies the decision to make the multiplicative inverse operation total by imposing that the multiplicative inverse of zero…

Rings and Algebras · Mathematics 2014-11-04 J. A. Bergstra , C. A. Middelburg

Meadows - commutative rings equipped with a total inversion operation - can be axiomatized by purely equational means. We study subvarieties of the variety of meadows obtained by extending the equational theory and expanding the signature.

Rings and Algebras · Mathematics 2017-12-05 Jan A. Bergstra , Inge Bethke

One of the main virtues of trees is to represent formal solutions of various functional equations which can be cast in the form of fixed point problems. Basic examples include differential equations and functional (Lagrange) inversion in…

Combinatorics · Mathematics 2013-02-12 Florent Hivert , Jean-Christophe Novelli , Jean-Yves Thibon

$\mathbb{Q}_0$ - the involutive meadow of the rational numbers - is the field of the rational numbers where the multiplicative inverse operation is made total by imposing $0^{-1}=0$. In this note, we prove that $\mathbb{Q}_0$ cannot be…

Rings and Algebras · Mathematics 2017-12-05 Jan A. Bergstra , Inge Bethke

A skew meadow is a non-commutative ring with an inverse operator satisfying two special equations and in which the inverse of zero is zero. All skew fields and products of skew fields can be viewed as skew meadows. Conversely, we give an…

Rings and Algebras · Mathematics 2009-01-08 J. A. Bergstra , Y. Hirshfeld , J. V. Tucker

Semifields are semirings in which every nonzero element has a multiplicative inverse. A rough classification uses the characteristic of the semifield, that is the isomorphism type of the semifield generated by the two neutral elements. For…

Algebraic Geometry · Mathematics 2017-09-21 Guillaume Tahar

Consider a commutative monoid $(M,+,0)$ and a biadditive binary operation $\mu \colon M \times M \to M$. We will show that under some additional general assumptions, the operation $\mu$ is automatically both associative and commutative. The…

Rings and Algebras · Mathematics 2024-06-18 Matthias Schötz
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