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| :<math>d(x_k,x)\to 0</math> as <math>k\to \infty</math> | | :<math>d(x_k,x)\to 0</math> as <math>k\to \infty</math> |
| ===Riesz-Fischer Theorem=== | | ===Riesz-Fischer Theorem=== |
| The vector space <math>L^1</math> is complete in its metric. <ref name="Stein">Elias M. Stein and Rami Shakarchi(2005), Real Analysis: measure theory, integration, & hilbert spaces, first edition</ref> | | The vector space <math>L^1</math> is complete in its metric induced by the <math>p</math>-norm. <ref name="Stein">Elias M. Stein and Rami Shakarchi(2005), Real Analysis: measure theory, integration, & hilbert spaces, first edition</ref> |
| ====Proof==== | | ====Proof==== |
| See Stein and Shakarchi | | See Stein and Shakarchi |
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| ==References== | | ==References== |
Introduction
Let be a measure space. From our study of integration[1], we know that if are integrable functions, the following functions are also integrable:
-
- , for
This shows that the set of integrable functions on any measurable space is a vector space. Furthermore, integration is a linear functional on this vector space, ie a linear function sending elements in our vector space to , one would like to use integration to define a norm on our vector space. However, if one were to check the axioms for a norm, one finds integration fails to be a norm by taking almost everywhere, then . In other words, there are non zero functions which has a zero integral. This motivates our definition of to be the set of integrable functions up to equivalence to sets of measure zero.
Space
In this section, we will construct .
Definition
Let denote the set of integrable functions on , ie . Define an equivalence relation: if a.e. Then . In some abuse of notation, we often refer to an element as a function, even though it really denotes the equivalence class of all functions in which are a.e. equivalent to .
To make sense of the definition, we need the following proposition:
Proposition: Let , then the following are equivalent:
- for all
-
- a.e.
Since a.e., a.e. Take a simple function, , such that , such must be a.e. Therefore,
Suppose the set does not have measure zero. Then either or has nonzero measure, where denotes and denotes . WLOG, assume has nonzero measure. Define the following sets , then from continuity from below, . This shows that there exists some such that , which implies that , contradicting 1.
With the proposition, we define our norm on to be . This is indeed a norm since:
-
-
- a.e
Completeness of space
A space with a metric is said to be complete if for every Cauchy sequence in (that is, as ) there exist such that in the sense that
- as
Riesz-Fischer Theorem
The vector space is complete in its metric induced by the -norm. [2]
Proof
See Stein and Shakarchi
References
- ↑ 1.0 1.1 Folland, Gerald B. (1999). Real Analysis: Modern Techniques and Their Applications, John Wiley and Sons, ISBN 0471317160, Second edition.
- ↑ Elias M. Stein and Rami Shakarchi(2005), Real Analysis: measure theory, integration, & hilbert spaces, first edition