Asymptotic gauges: Generalization of Colombeau type algebras

Giordano, Paolo; Baglini, Lorenzo Luperi

doi:10.1002/mana.201400278

Cited by 10 publications

(30 citation statements)

References 13 publications

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“…(see also [5,12]). A step towards the analysis of these problems is the generalization of the role of the infinite nets (ε −n ) ∈ R (0,1] , n ∈ N, appearing in the definition of Colombeau algebras, see (1.1).…”

Section: If D α : D ( ) −→ D ( ) Is the Usual α-Derivation Of Distribmentioning

confidence: 99%

“…A step towards the analysis of these problems is the generalization of the role of the infinite nets (ε −n ) ∈ R (0,1] , n ∈ N, appearing in the definition of Colombeau algebras, see (1.1). An understanding of the role of the nets (ε −n ) ∈ R (0, 1] has already been realized through the notions of asymptotic scales, (C, E, P)-algebras, (M, N , V P )-algebras, exponent weights and asymptotic gauges, see [6][7][8][9]12,14,15] and references therein.…”

Section: If D α : D ( ) −→ D ( ) Is the Usual α-Derivation Of Distribmentioning

confidence: 99%

“…In fact, Colombeau AG-algebras include in the same abstract framework all known Colombeau-like algebras, like the special one G s , the full one G e , [5], the NSA based algebra of asymptotic functionsĜ, [23], the diffeomorphism invariant algebras G d , G 2 andĜ, [5], the Egorov algebra, [10,11,25], and the algebra of non-standard smooth functions * C ∞ ( ), [4,18]; see [12,13] and below. The simplicity of the approach with AGs lies, for all the algebras mentioned above, in the use of the simple logical structure of quantifiers that characterizes the special algebra G s .…”

Section: If D α : D ( ) −→ D ( ) Is the Usual α-Derivation Of Distribmentioning

confidence: 99%

“…We shall frequently use (1.2) as a paradigmatic motivation, even if the solution of this trivial ODE is not one of the aim of the present paper. For the solution and uniqueness of all R-linear ODE in a minimal Colombeau AG-algebra, see [12].…”

Section: If D α : D ( ) −→ D ( ) Is the Usual α-Derivation Of Distribmentioning

confidence: 99%

“…In [12], we introduced the notion of asymptotic gauge. The idea was to use it as an asymptotic scale that generalizes the role of the polynomial family (ε n ) ε∈(0,1],n∈N in classical constructions of Colombeau algebras.…”

Section: Asymptotic Gaugesmentioning

confidence: 99%

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The category of Colombeau algebras

Baglini

Giordano

2016

Monatsh Math

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Since the beginning of Colombeau's the theory of algebras of generalized functions, the role of its characteristic polynomial growth versus a more general condition has been explored. Recently, we introduced the notion of asymptotic gauge (AG), and we used it to study Colombeau AG-algebras. This construction concurrently generalizes many different algebras used in Colombeau's theory and, at the same time, allows for more general growth scales. In this paper, we study the categorical properties of Colombeau AG-algebras with respect to the choice of the AG. The main aim of the paper is to study suitable functors to relate differential equations framed in algebras having different growth scales.

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Section: If D α : D ( ) −→ D ( ) Is the Usual α-Derivation Of Distribmentioning

confidence: 99%

Section: If D α : D ( ) −→ D ( ) Is the Usual α-Derivation Of Distribmentioning

confidence: 99%

Section: If D α : D ( ) −→ D ( ) Is the Usual α-Derivation Of Distribmentioning

confidence: 99%

Section: If D α : D ( ) −→ D ( ) Is the Usual α-Derivation Of Distribmentioning

confidence: 99%

Section: Asymptotic Gaugesmentioning

confidence: 99%

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The category of Colombeau algebras

Baglini

Giordano

2016

Monatsh Math

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A Topological Approach to Non-Archimedean Mathematics

Benci

Baglini

2016

Springer Proceedings in Mathematics &Amp; Statistics

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Non-Archimedean mathematics (in particular, nonstandard analysis) allows to construct some useful models to study certain phenomena arising in PDE's; for example, it allows to construct generalized solutions of differential equations and variational problems that have no classical solution. In this paper we introduce certain notions of non-Archimedean mathematics (in particular, of nonstandard analysis) by means of an elementary topological approach; in particular, we construct non-Archimedean extensions of the reals as appropriate topological completions of R. Our approach is based on the notion of Λ-limit for real functions, and it is called Λ-theory. It can be seen as a topological generalization of the α-theory presented in [6], and as an alternative topological presentation of the ultrapower construction of nonstandard extensions (in the sense of [22]). To motivate the use of Λ-theory for applications we show how to use it to solve a minimization problem of calculus of variations (that does not have classical solutions) by means of a particular family of generalized functions, called ultrafunctions.

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