Modes of Convergence: Difference between revisions

Revision as of 20:46, 18 December 2020

Relevant Definitions^[1]

Denote our measure space as $(X,{\mathcal {M}},\mu )$ . Note that a property p holds for almost every $x\in X$ if the set $\{x\in X:p{\text{ doesn't hold }}\}$ has measure zero.

A sequence of measurable functions $\{f_{n}\}$ converges pointwise if $f_{n}(x)\to f(x)$ for all $x\in X$ .
A sequence of measureable functions $\{f_{n}\}$ converges uniformly if $\sup _{x\in X}|f_{n}(x)-f(x)|\to 0$ .
A sequence of measurable functions $\{f_{n}\}$ converges to $f$ pointwise almost everywhere if $f_{n}(x)\to f(x)$ for almost every $x$ , or $\mu (\{x:f(x)\neq \lim _{n\to \infty }f(x)\})=0$ .
A sequence of measurable functions $\{f_{n}\}$ converges in $L^{1}$ if $\int |f_{n}-f|\to 0.$

check Convergence in Measure for convergence in measure.

Relevant Properties ^[2]

$f_{n}\to f$ through uniform convergence implies $f_{n}\to f$ through pointwise convergence, which in turn implies $f_{n}\to f$ pointwise a.e. convergence.
$f_{n}\to f$ through $L^{1}$ convergence implies $f_{n}\to f$ through pointwise a.e convergence up to a subsequence. This follows because $L^{1}$ convergence means $f_{n}\to f$ in measure, and that in turn sugggests there exists a subsequence $f_{n_{k}}$ such that $f_{n_{k}}\to f$ pointwise a.e.
$f_{n}\to f$ Pointwise a.e. convergence, equipped with dominating function, implies $f_{n}\to f$ in $L^{1}$ . To see example of why we need a dominating function, read Dominated Convergence Theorem, particularly applications of the theorem.
Convergence in Measure lists relationships between convergence in measure and other forms of convergence.

Proof $L^{1}$ convergence implies convergence in measure

Fix $\epsilon >0,$ define $E_{n,\epsilon }=\{x:|f_{n}(x)-f(x)|\geq \epsilon \}$ We can see that that

$\int _{E_{n,\epsilon }}\epsilon \leq \int _{E_{n,\epsilon }}|f_{n}-f|\leq \int |f_{n}-f|.$

we can see by $L^{1}$ convergence that $\lim _{n\to \infty }\int |f_{n}-f|=0,$ meaning that $\lim _{n\to \infty }\int _{E_{n,\epsilon }}\epsilon =\lim _{n\to \infty }\epsilon \mu (E_{n,\epsilon })=0,$

or $\lim _{n\to \infty }\mu (E_{n,\epsilon })=0$

↑ Craig, Katy. MATH 201A Lecture 17. UC Santa Barbara, Fall 2020.
↑ Craig, Katy. MATH 201A Lecture 18. UC Santa Barbara, Fall 2020.

[Craig-1] Craig, Katy. MATH 201A Lecture 17. UC Santa Barbara, Fall 2020.

[Craig,_Katy-2] Craig, Katy. MATH 201A Lecture 18. UC Santa Barbara, Fall 2020.

[1]

[2]

@@ Line 12: / Line 12: @@
 * <math>f_n \to f</math> Pointwise a.e. convergence, equipped with dominating function, implies <math>f_n \to f</math>  in  <math>L^1</math>. To see example of why we need a dominating function, read [[Dominated Convergence Theorem]], particularly applications of the theorem.
 * [[Convergence in Measure]] lists relationships between convergence in measure and other forms of convergence.
+== Proof <math>L^1</math> convergence implies convergence in measure==
+Fix <math> \epsilon >0,  </math> define
+<math>E_{n, \epsilon}  = \{x: |f_n(x) - f(x)| \geq \epsilon\}</math>
+We can see that that
+<math> \int_{E_{n,\epsilon}}\epsilon \leq  \int_{E_{n,\epsilon}}|f_n - f|\leq  \int|f_n - f|.  </math>
+we can see by <math>L^1</math> convergence that <math>\lim_{n \to \infty}\int |f_n-f| = 0, </math>
+meaning that
+<math> \lim_{n \to \infty} \int_{E_{n,\epsilon}}\epsilon = \lim_{n \to \infty}\epsilon \mu(E_{n,\epsilon}) = 0,</math>
+or
+<math> \lim_{n \to \infty}   \mu(E_{n,\epsilon}) = 0</math>

Modes of Convergence: Difference between revisions

Revision as of 20:46, 18 December 2020

Relevant Definitions[1]

Relevant Properties [2]

Proof L 1 {\displaystyle L^{1}} convergence implies convergence in measure

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Relevant Definitions^[1]

Relevant Properties ^[2]

Proof $L^{1}$ convergence implies convergence in measure