Difference between revisions of "Uniform boundedness"
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− | + | ''from above (below)'' | |
− | + | A property of a family of real-valued functions $ f _ \alpha : X \rightarrow \mathbf R $, | |
+ | where $ \alpha \in {\mathcal A} $, | ||
+ | $ {\mathcal A} $ | ||
+ | is an index set and $ X $ | ||
+ | is an arbitrary set. It requires that there is a constant $ c > 0 $ | ||
+ | such that for all $ \alpha \in {\mathcal A} $ | ||
+ | and all $ x \in X $ | ||
+ | the inequality $ f _ \alpha ( x) \leq c $( | ||
+ | respectively, $ f _ \alpha ( x) \geq - c $) | ||
+ | holds. | ||
− | + | A family of functions $ f _ \alpha : X \rightarrow \mathbf R $, | |
+ | $ \alpha \in {\mathcal A} $, | ||
+ | is called uniformly bounded if it is uniformly bounded both from above and from below. | ||
− | + | The notion of uniform boundedness of a family of functions has been generalized to mappings into normed and semi-normed spaces: A family of mappings $ f _ \alpha : X \rightarrow Y $, | |
+ | where $ \alpha \in {\mathcal A} $, | ||
+ | $ X $ | ||
+ | is an arbitrary set and $ Y $ | ||
+ | is a semi-normed (normed) space with semi-norm (norm) $ \| \cdot \| _ {Y} $, | ||
+ | is called uniformly bounded if there is a constant $ c > 0 $ | ||
+ | such that for all $ \alpha \in {\mathcal A} $ | ||
+ | and $ x \in X $ | ||
+ | the inequality $ \| f _ \alpha ( x) \| _ {Y} \leq c $ | ||
+ | holds. If a semi-norm (norm) is introduced into the space $ \{ X \rightarrow Y \} $ | ||
+ | of bounded mappings $ f: X \rightarrow Y $ | ||
+ | by the formula | ||
− | + | $$ | |
+ | \| f \| _ {\{ X \rightarrow Y \} } = \sup _ {x \in X } \ | ||
+ | \| f ( x) \| _ {Y} , | ||
+ | $$ | ||
+ | then uniform boundedness of a set of functions $ f _ \alpha : X \rightarrow Y $, | ||
+ | $ \alpha \in U $, | ||
+ | means boundedness of this set in the space $ \{ X \rightarrow Y \} $ | ||
+ | with the semi-norm $ \| \cdot \| _ {\{ X \rightarrow Y \} } $. | ||
+ | The concept of uniform boundedness from below and above has been generalized to the case of mappings $ f: X \rightarrow Y $ | ||
+ | into a set $ Y $ | ||
+ | that is ordered in some sense. | ||
====Comments==== | ====Comments==== | ||
− | The uniform boundedness theorem is as follows. Let | + | The uniform boundedness theorem is as follows. Let $ X $ |
+ | be a linear topological space that is not a countable union of closed nowhere-dense subsets. Let $ \{ {T _ \alpha } : {\alpha \in {\mathcal A} } \} $ | ||
+ | be a family of continuous mappings of $ X $ | ||
+ | into a quasi-normed linear space $ Y $( | ||
+ | cf. [[Quasi-norm|Quasi-norm]]). Assume that | ||
− | + | $$ | |
+ | \| T _ \alpha ( x+ y) \| \leq \| T _ \alpha ( x) \| + | ||
+ | \| T _ \alpha ( y) \| , | ||
+ | $$ | ||
− | + | $$ | |
+ | \| T _ \alpha ( ax) \| = a \| T _ \alpha ( x) \| \ \textrm{ for } a \geq 0. | ||
+ | $$ | ||
− | Now, if the set | + | Now, if the set $ \{ {T _ \alpha ( x) } : {\alpha \in {\mathcal A} } \} $ |
+ | is bounded for each $ x \in X $, | ||
+ | then | ||
− | + | $$ | |
+ | \lim\limits _ {\alpha \rightarrow 0 } T _ \alpha ( x) = 0 | ||
+ | $$ | ||
− | uniformly in | + | uniformly in $ \alpha $. |
+ | Here, the convergence to zero is strong convergence, i.e. in the quasi-norm of $ Y $. | ||
− | A corollary is the resonance theorem (sometimes itself called the uniform boundedness theorem): Let | + | A corollary is the resonance theorem (sometimes itself called the uniform boundedness theorem): Let $ \{ {T _ \alpha } : {\alpha \in {\mathcal A} } \} $ |
+ | be a family of bounded linear operators from a Banach space $ X $ | ||
+ | into a normed linear space $ Y $. | ||
+ | Then the boundedness of $ \{ {\| T _ \alpha ( x) \| } : {\alpha \in {\mathcal A} } \} $ | ||
+ | for each $ x \in X $ | ||
+ | implies the boundedness of $ \{ {\| T _ \alpha \| } : {\alpha \in {\mathcal A} } \} $, | ||
+ | and if $ {\mathcal A} = \mathbf N $ | ||
+ | and $ \lim\limits _ {n\rightarrow \infty } T _ {n} ( x) = T( x) $ | ||
+ | exists for each $ x \in X $, | ||
+ | then $ T $ | ||
+ | is also a bounded linear operator $ X \rightarrow Y $. | ||
Cf. also [[Banach–Steinhaus theorem|Banach–Steinhaus theorem]] (also called the uniform boundedness principle) and [[Equicontinuity|Equicontinuity]]. | Cf. also [[Banach–Steinhaus theorem|Banach–Steinhaus theorem]] (also called the uniform boundedness principle) and [[Equicontinuity|Equicontinuity]]. |
Latest revision as of 08:27, 6 June 2020
from above (below)
A property of a family of real-valued functions $ f _ \alpha : X \rightarrow \mathbf R $, where $ \alpha \in {\mathcal A} $, $ {\mathcal A} $ is an index set and $ X $ is an arbitrary set. It requires that there is a constant $ c > 0 $ such that for all $ \alpha \in {\mathcal A} $ and all $ x \in X $ the inequality $ f _ \alpha ( x) \leq c $( respectively, $ f _ \alpha ( x) \geq - c $) holds.
A family of functions $ f _ \alpha : X \rightarrow \mathbf R $, $ \alpha \in {\mathcal A} $, is called uniformly bounded if it is uniformly bounded both from above and from below.
The notion of uniform boundedness of a family of functions has been generalized to mappings into normed and semi-normed spaces: A family of mappings $ f _ \alpha : X \rightarrow Y $, where $ \alpha \in {\mathcal A} $, $ X $ is an arbitrary set and $ Y $ is a semi-normed (normed) space with semi-norm (norm) $ \| \cdot \| _ {Y} $, is called uniformly bounded if there is a constant $ c > 0 $ such that for all $ \alpha \in {\mathcal A} $ and $ x \in X $ the inequality $ \| f _ \alpha ( x) \| _ {Y} \leq c $ holds. If a semi-norm (norm) is introduced into the space $ \{ X \rightarrow Y \} $ of bounded mappings $ f: X \rightarrow Y $ by the formula
$$ \| f \| _ {\{ X \rightarrow Y \} } = \sup _ {x \in X } \ \| f ( x) \| _ {Y} , $$
then uniform boundedness of a set of functions $ f _ \alpha : X \rightarrow Y $, $ \alpha \in U $, means boundedness of this set in the space $ \{ X \rightarrow Y \} $ with the semi-norm $ \| \cdot \| _ {\{ X \rightarrow Y \} } $.
The concept of uniform boundedness from below and above has been generalized to the case of mappings $ f: X \rightarrow Y $ into a set $ Y $ that is ordered in some sense.
Comments
The uniform boundedness theorem is as follows. Let $ X $ be a linear topological space that is not a countable union of closed nowhere-dense subsets. Let $ \{ {T _ \alpha } : {\alpha \in {\mathcal A} } \} $ be a family of continuous mappings of $ X $ into a quasi-normed linear space $ Y $( cf. Quasi-norm). Assume that
$$ \| T _ \alpha ( x+ y) \| \leq \| T _ \alpha ( x) \| + \| T _ \alpha ( y) \| , $$
$$ \| T _ \alpha ( ax) \| = a \| T _ \alpha ( x) \| \ \textrm{ for } a \geq 0. $$
Now, if the set $ \{ {T _ \alpha ( x) } : {\alpha \in {\mathcal A} } \} $ is bounded for each $ x \in X $, then
$$ \lim\limits _ {\alpha \rightarrow 0 } T _ \alpha ( x) = 0 $$
uniformly in $ \alpha $. Here, the convergence to zero is strong convergence, i.e. in the quasi-norm of $ Y $.
A corollary is the resonance theorem (sometimes itself called the uniform boundedness theorem): Let $ \{ {T _ \alpha } : {\alpha \in {\mathcal A} } \} $ be a family of bounded linear operators from a Banach space $ X $ into a normed linear space $ Y $. Then the boundedness of $ \{ {\| T _ \alpha ( x) \| } : {\alpha \in {\mathcal A} } \} $ for each $ x \in X $ implies the boundedness of $ \{ {\| T _ \alpha \| } : {\alpha \in {\mathcal A} } \} $, and if $ {\mathcal A} = \mathbf N $ and $ \lim\limits _ {n\rightarrow \infty } T _ {n} ( x) = T( x) $ exists for each $ x \in X $, then $ T $ is also a bounded linear operator $ X \rightarrow Y $.
Cf. also Banach–Steinhaus theorem (also called the uniform boundedness principle) and Equicontinuity.
References
[a1] | K. Yosida, "Functional analysis" , Springer (1978) pp. 68ff |
[a2] | W. Rudin, "Real and complex analysis" , McGraw-Hill (1966) pp. 98 |
Uniform boundedness. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Uniform_boundedness&oldid=14233