Partial fraction decomposition: Difference between revisions

From formulasearchengine
Jump to navigation Jump to search
en>D.Lazard
m References: sorting by date
 
en>D.Lazard
Basic principles: better wikilinks + ce
 
(One intermediate revision by the same user not shown)
Line 1: Line 1:
In [[mathematics]], the '''uniform boundedness principle''' or '''Banach–Steinhaus theorem''' is one of the fundamental results in [[functional analysis]]. Together with the [[Hahn–Banach theorem]] and the [[open mapping theorem (functional analysis)|open mapping theorem]], it is considered one of the cornerstones of the field.  In its basic form, it asserts that for a family of [[continuous  linear operator]]s (and thus bounded operators) whose domain is a [[Banach space]], pointwise boundedness is equivalent to uniform boundedness in operator norm.
Wordpress has replaced nearly all of my 'normal' html websites. Just obtain the [http://musclestats.com/drupal2/dedicated-server-hostgator HostGator 1 cent coupon] and avail all of the services of a regular package at free of price for a month. Indeed they may be one of the best serves you can ever find and they are inside my 'A list' and listed below are the keypoints of Hostgator's success. Great for finding the perfect site look. Among the list of worlds most significant and most preferred Internet hosting enterprise is the HostGator. All in all, it's not that difficult to make the right choice for hosting when you're reading good web hosting reviews - but don't rush it unless it's absolutely necessary, and ensure you're looking at the full picture before making a final decision. You'll need to be good at describing things, packaging them up, and maintaining customer satisfaction, but it isn't that hard. After inception of HostGator, clients started selecting their host, based on the reliability and [http://search.about.com/?q=technical+support technical support] in case of technical glitches. Although I am not using Hostgator Website hosting for this blog, I am using it for 2 associated with my personal interferance websites and I am truly happy with their providers as well as client facilitates. It has been in existence for more than a decade which ensures shoppers with the most effective web hosting [http://Www.Answers.com/topic/service service] possible.<br><br><br><br>Likewise, many beginner bloggers want to make a little side income with their blog. Even if every week or so, every other month, are supported, I believe that the process will check it works properly. Hostgator has optimized their servers to run wordpress like a charm. Or plan to pay your programmer a lot of money performing repair work. But after the years I have put into looking, I managed to come up with a list of places. No never-ending loops and all have been verified that they pay. The pricing is all reasonable in my opinion, especially considering what you receive. This implies that there is a very minimal likelihood of server crashing thus, making sure that the shoppers websites will likely be up and running all of the time.
 
The theorem was first published in 1927 by [[Stefan Banach]] and [[Hugo Steinhaus]] but it was also proven independently by [[Hans Hahn (mathematician)|Hans Hahn]].
 
== Uniform boundedness principle ==
<blockquote>'''Theorem (Uniform Boundedness Principle).''' Let ''X'' be a [[Banach space]] and ''Y'' be a [[normed vector space]]. Suppose that ''F'' is a collection of continuous linear operators from ''X'' to ''Y''. If for all ''x'' in ''X'' one has
 
:<math>\sup\nolimits_{T \in F} \|T(x)\|_Y  < \infty, </math>
 
then
 
:<math>\sup\nolimits_{T \in F} \|T\|_{B(X,Y)}  < \infty.</math></blockquote>
 
The completeness of ''X'' enables the following short proof, using the [[Baire category theorem]].<br ><br >
 
'''Proof.''' Suppose that for every ''x'' in the Banach space ''X'', one has:
 
:<math>\sup\nolimits_{T \in F} \|T (x)\|_Y  < \infty.</math>
 
For every integer ''n'' in '''N''', let
 
:<math> X_n = \left  \{x \in X \ : \ \sup\nolimits_{T \in F} \|T (x)\|_Y \le n \right \}. </math>
 
The set <math>X_n</math> is a [[closed set]] and by the assumption,
 
:<math>\bigcup\nolimits_{n \in \mathbf{N}} X_n = X \neq \varnothing.</math>
 
By the [[Baire category theorem]] for the non-empty [[complete metric space]]&nbsp;''X'', there exists ''m'' such that
<math> X_m</math> has non-empty [[Interior (topology)|interior]], ''i.e.'', there exist <math>x_0 \in X_m</math> and {{nowrap|ε &gt; 0}} such that
 
:<math> \overline{B_\varepsilon (x_0)} := \{x \in X \,:\, \|x - x_0\| \le \varepsilon \} \subseteq  X_m.</math>
 
Let ''u'' ∈ ''X'' with {{nowrap|ǁ''u''ǁ &le; 1}} and {{nowrap|''T'' ∈ ''F''}}.  One has that:
 
:<math>\begin{align}
\|T(u) \|_Y &= \varepsilon^{-1} \left \|T \left( x_0 + \varepsilon u \right) - T(x_0) \right \|_Y    & [\text{by linearity of } T ] \\
&\leq \varepsilon^{-1} \left ( \left\| T (x_0 + \varepsilon u) \right\|_Y + \left\| T (x_0) \right\|_Y \right ) \\
&\leq \varepsilon^{-1} (m + m).  & [ \text{since} \ x_0 + \varepsilon u, \ x_0 \in X_m ] \\
\end{align}</math>
 
Taking the supremum over ''u'' in the unit ball of&nbsp;''X'', it follows that
 
:<math> \sup\nolimits_{T \in F} \|T\|_{B(X,Y)}  \leq 2 \varepsilon^{-1} m < \infty.</math>
 
==Corollaries==
<blockquote>'''Corollary.''' If a sequence of bounded operators (''T<sub>n</sub>'') converges pointwise, that is, the limit of {''T<sub>n</sub>''(''x'')} exists for all ''x'' in ''X'', then these pointwise limits define a bounded operator ''T''.</blockquote>
 
Note it is not claimed above that ''T<sub>n</sub>'' converges to ''T'' in operator norm, i.e. uniformly on bounded sets. (However, since {''T<sub>n</sub>''} is bounded in operator norm, and the limit operator ''T'' is continuous, a standard [[3-epsilon estimate|"3-ε" estimate]] shows that ''T<sub>n</sub>'' converges to ''T'' uniformly on ''compact'' sets.)
 
<blockquote>'''Corollary.''' Any weakly bounded subset S in a normed space Y is bounded''</blockquote>
 
Indeed, the elements of ''S'' define a pointwise bounded family of continuous linear forms on the Banach space ''X''&nbsp;=&nbsp;''Y*'', continuous dual of ''Y''. By the uniform boundedness principle, the norms of elements of ''S'', as functionals on ''X'', that is, norms in the second dual ''Y**'', are bounded. But for every ''s'' in ''S'', the norm in the second dual coincides with the norm in ''Y'', by a consequence of the [[Hahn–Banach theorem]].
 
Let ''L''(''X'',&nbsp;''Y'') denote the continuous operators from ''X'' to ''Y'', with the operator norm. If the collection ''F'' is unbounded in ''L''(''X'',&nbsp;''Y''), then by the uniform boundedness principle, we have:
 
:<math> R = \left \{ x \in X  \ : \ \sup\nolimits_{T \in F} \|Tx\|_Y = \infty \right \} \neq \varnothing</math>
 
In fact, ''R'' is dense in ''X''. The complement of ''R'' in ''X'' is the countable union of closed sets &cup;''X<sub>n</sub>''. By the argument used in proving the theorem, each ''X<sub>n</sub>'' is [[nowhere dense]], i.e. the subset &cup;''X<sub>n</sub>'' is ''of first category''. Therefore ''R'' is the complement of a subset of first category in a  Baire space. By definition of a Baire space, such sets (called ''residual sets'') are dense. Such reasoning leads to the '''principle of condensation of singularities''', which can be formulated as follows:
 
<blockquote>'''Theorem.''' Let ''X'' be a Banach space, {''Y<sub>n</sub>''} a sequence of normed vector spaces, and ''F<sub>n</sub>'' a unbounded family in ''L''(''X'', ''Y<sub>n</sub>''). Then the set
 
:<math> R = \left \{ x \in X \ : \ \forall n \in \mathbf{N} : \sup\nolimits_{T \in F_n} \|Tx\|_Y = \infty \right \}</math>
 
is dense in ''X''.</blockquote>
 
'''Proof.''' The complement of ''R'' is the countable union
 
:<math>\bigcup\nolimits_{n,m} \left \{ x \in X \ : \ \sup\nolimits_{T \in F_n} \|Tx\|_Y \le m \right \}</math>
 
of sets of first category. Therefore its residual set ''R'' is dense.
 
==Example: pointwise convergence of Fourier series==
Let '''T''' be the [[circle group|circle]], and let ''C''('''T''') be the Banach space of continuous functions on '''T''', with the [[uniform norm]]. Using the uniform boundedness principle, one can show that the Fourier series, "typically", does not converge pointwise for elements in ''C''('''T''').
 
For ''f'' in ''C''('''T'''), its [[Fourier series]] is defined by
 
:<math>\sum_{k \in \mathbf{Z}} \hat{f}(k) e^{ikx} = \sum_{k \in \mathbf{Z}}\frac{1}{2\pi} \left (\int_0 ^{2 \pi} f(t) e^{-ikt} dt \right) e^{ikx},</math>
 
and the ''N''-th symmetric partial sum is
 
:<math> S_N(f)(x) = \sum_{k=-N}^N \hat{f}(k) e^{ikx} =  \frac{1}{2 \pi} \int_0 ^{2 \pi} f(t) D_N(x - t) \, dt,</math>
 
where ''D<sub>N</sub>'' is the ''N''-th [[Dirichlet kernel]]. Fix ''x'' in '''T''' and consider the convergence of {''S<sub>N</sub>''(''f'')(''x'')}. The functional φ<sub>''N,x''</sub> : ''C''('''T''')&nbsp;→ '''C''' defined by
 
:<math>\varphi_{N, x} (f) =  S_N(f)(x), \qquad f \in C(\mathbf{T}),</math>
 
is bounded. The norm of φ<sub>''N,x''</sub>, in the dual of ''C''('''T'''), is the norm of the signed measure (2π)<sup>−1</sup>''D''<sub>''N''</sub>(''x''−''t'')&nbsp;d''t'', namely
 
:<math> \left \| \varphi_{N,x} \right \| =  \frac{1}{2 \pi} \int_0 ^{2 \pi} \left | D_N(x-t) \right  | \, dt =  \frac{1}{2 \pi} \int_0 ^{2 \pi} \left | D_N(s) \right  | \, ds = \left \|  D_N \right \|_{L^1(\mathbf{T})}.</math>
 
One can verify that
 
:<math>\frac{1}{2 \pi} \int_0 ^{2 \pi} | D_N(t) | \, dt \ge \int_0^\pi \frac{\left |\sin\left ( (N+\tfrac{1}{2})t \right )\right|} t \, dt \to \infty.</math>
 
So the collection {φ<sub>''N,x''</sub>} is unbounded in ''C''('''T''')*, the dual of ''C''('''T'''). Therefore by the uniform boundedness principle, for any ''x'' in '''T''', the set of continuous functions whose Fourier series diverges at ''x'' is dense in ''C''('''T''').
 
More can be concluded by applying the principle of condensation of singularities. Let {''x<sub>m</sub>''} be a dense sequence in '''T'''. Define φ<sub>''N,x<sub>m</sub>''</sub> in the similar way as above. The principle of condensation of singularities then says that the set of continuous functions whose Fourier series diverges at each ''x<sub>m</sub>'' is dense in ''C''('''T''') (however, the Fourier series of a continuous function ''f'' converges to ''f''(''x'') for almost every ''x'' in '''T''', by [[Carleson's theorem]]).
 
== Generalizations ==
The least restrictive setting for the uniform boundedness principle is a [[barrelled space]] where the following generalized version of the theorem holds {{harv|Bourbaki|1987|loc=Theorem III.2.1}}:
 
<blockquote>'''Theorem.''' Given a barrelled space ''X'' and a [[locally convex space]] ''Y'', then any family of pointwise bounded [[continuous linear mapping]]s from ''X'' to ''Y'' is [[equicontinuous]] (even [[uniformly equicontinuous]]).</blockquote>
 
Alternatively, the statement also holds whenever ''X'' is a [[Baire space]] and ''Y'' is a locally convex space {{harv|Shtern|2001}}.
 
{{harvtxt|Dieudonné|1970}} proves a weaker form of this theorem with [[Fréchet space]]s rather than the usual Banach spaces.  Specifically,
 
<blockquote>'''Theorem.''' Let ''X'' be a Fréchet space, ''Y'' a normed space, and ''H'' a set of continuous linear mappings of ''X'' into ''Y''.  If for every ''x'' in ''X''
:<math>\sup\nolimits_{u\in H}\|u(x)\|<\infty,</math>
then the family ''H'' is equicontinuous.</blockquote>
 
==See also==
*[[Barrelled space]], a [[topological vector space]] with minimum requirements for the Banach Steinhaus theorem to hold
 
== References ==
*{{citation|first1=Stefan|last1=Banach|authorlink1=Stefan Banach|first2=Hugo|last2=Steinhaus|authorlink2=Hugo Steinhaus| url=http://matwbn.icm.edu.pl/ksiazki/fm/fm9/fm918.pdf |title=Sur le principe de la condensation de singularités|journal=[[Fundamenta Mathematicae]]| volume=9| pages=50–61|year=1927}}. {{fr}}
*{{citation|first=Nicolas|last=Bourbaki|authorlink=Nicolas Bourbaki|series=Elements of mathematics|title=Topological vector spaces|publisher=Springer|year=1987|isbn=978-3-540-42338-6}}
*{{citation|first=Jean|last=Dieudonné|authorlink=Jean Dieudonné|title=Treatise on analysis, Volume 2|year=1970|publisher=Academic Press}}.
*{{citation|first=Walter|last=Rudin|authorlink=Walter Rudin|title=Real and complex analysis|publisher=McGraw-Hill|year=1966}}.
*{{springer|Banach–Steinhaus theorem|first=A.I.|last=Shtern|year=2001|id=b/b015200}}.
 
[[Category:Functional analysis]]
[[Category:Articles containing proofs]]
[[Category:Mathematical principles]]
[[Category:Theorems in functional analysis]]

Latest revision as of 18:04, 2 December 2014

Wordpress has replaced nearly all of my 'normal' html websites. Just obtain the HostGator 1 cent coupon and avail all of the services of a regular package at free of price for a month. Indeed they may be one of the best serves you can ever find and they are inside my 'A list' and listed below are the keypoints of Hostgator's success. Great for finding the perfect site look. Among the list of worlds most significant and most preferred Internet hosting enterprise is the HostGator. All in all, it's not that difficult to make the right choice for hosting when you're reading good web hosting reviews - but don't rush it unless it's absolutely necessary, and ensure you're looking at the full picture before making a final decision. You'll need to be good at describing things, packaging them up, and maintaining customer satisfaction, but it isn't that hard. After inception of HostGator, clients started selecting their host, based on the reliability and technical support in case of technical glitches. Although I am not using Hostgator Website hosting for this blog, I am using it for 2 associated with my personal interferance websites and I am truly happy with their providers as well as client facilitates. It has been in existence for more than a decade which ensures shoppers with the most effective web hosting service possible.



Likewise, many beginner bloggers want to make a little side income with their blog. Even if every week or so, every other month, are supported, I believe that the process will check it works properly. Hostgator has optimized their servers to run wordpress like a charm. Or plan to pay your programmer a lot of money performing repair work. But after the years I have put into looking, I managed to come up with a list of places. No never-ending loops and all have been verified that they pay. The pricing is all reasonable in my opinion, especially considering what you receive. This implies that there is a very minimal likelihood of server crashing thus, making sure that the shoppers websites will likely be up and running all of the time.