Cryptanalysis of the Lorenz cipher: Difference between revisions

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{{no footnotes|date=November 2011}}
In [[functional analysis]], the [[Maurice Fréchet|Fréchet]]-[[Andrey Kolmogorov|Kolmogorov]] theorem (the names of [[Marcel Riesz|Riesz]] or [[André Weil|Weil]] are sometimes added as well) gives a necessary and sufficient condition for a set of functions to be [[relatively compact]] in an [[Lp space|L<sup>p</sup> space]]. It can be thought of as an L<sup>p</sup> version of the [[Arzelà-Ascoli theorem]], from which it can be deduced.
 
== Statement ==
Let <math>B</math> be a bounded set in <math>L^p(\mathbb{R}^n)</math>, with <math>p\in[1,\infty)</math>.
 
The subset ''B'' is [[Relatively compact subspace|relatively compact]] if and only if the following properties hold:
#<math>\lim_{r\to\infty}\int_{|x|>r}\left|f\right|^p=0</math> uniformly on ''B'',
#<math>\lim_{a\to 0}\Vert\tau_a f-f\Vert_{L^p(\mathbb{R}^n)} = 0</math> uniformly on ''B'',
where <math>\tau_a f</math> denotes the translation of <math>f</math> by <math>a</math>, that is, <math>\tau_a f(x)=f(x-a) .</math>
 
The second property can be stated as <math>\forall \varepsilon >0 \, \, \exists \delta >0  </math> such that <math>\Vert\tau_a f-f\Vert_{L^p(\mathbb{R}^n)} < \varepsilon \, \, \forall f \in B, \forall a</math> with <math>|a|<\delta .</math>
 
== References ==
* {{cite book
  | last = Brezis
  | first = Haïm
  | authorlink = Haïm Brezis
  | title = Functional analysis, Sobolev spaces, and partial differential equations
  | publisher = [[Springer-Verlag|Springer]]
  | series = Universitext
  | year = 2010
  | isbn = 978-0-387-70913-0
  | page = 111
}}
* [[Marcel Riesz]], « [http://acta.fyx.hu/acta/showCustomerArticle.action?id=5397&dataObjectType=article Sur les ensembles compacts de fonctions sommables] », dans ''[[Acta Scientiarum Mathematicarum|Acta Sci. Math.]]'', vol. 6, 1933, p.&nbsp;136–142
* {{cite book
  | last = Precup
  | first = Radu
  | title = Methods in nonlinear integral equations
  | publisher = [[Springer-Verlag|Springer]]
  | year = 2002
  | isbn = 978-1-4020-0844-3
  | page = 21
}}
 
{{DEFAULTSORT:Frechet-Kolmogorov Theorem}}
[[Category:Theorems in functional analysis]]
[[Category:Compactness theorems]]
 
 
{{Mathanalysis-stub}}

Revision as of 20:22, 12 December 2013

Template:No footnotes In functional analysis, the Fréchet-Kolmogorov theorem (the names of Riesz or Weil are sometimes added as well) gives a necessary and sufficient condition for a set of functions to be relatively compact in an Lp space. It can be thought of as an Lp version of the Arzelà-Ascoli theorem, from which it can be deduced.

Statement

Let B be a bounded set in Lp(n), with p[1,).

The subset B is relatively compact if and only if the following properties hold:

  1. limr|x|>r|f|p=0 uniformly on B,
  2. lima0τaffLp(n)=0 uniformly on B,

where τaf denotes the translation of f by a, that is, τaf(x)=f(xa).

The second property can be stated as ε>0δ>0 such that τaffLp(n)<εfB,a with |a|<δ.

References


Template:Mathanalysis-stub