Notes:Measure theory plan
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Revision as of 11:59, 24 March 2016 by Alec (Talk | contribs) (Adding things I forgot to mention, some other notes)
Purpose
This document is the plan for the measure theory notation and development on this site.
Plan
- Introduce ring of sets
- PRE-MEASURE (\bar{\mu} ) - Introduce a (positive) extended real valued countably additive set function, \bar{\mu} on that ring. This will be a pre-measure and these are easy to create (use Lebesgue measure as example) which is why they're the first step.
- OUTER-MEASURE (\mu^*) - a construct named because it measures from the outside of a set and comes down (the inf), this lets us "measure" on a power-set like construction (a hereditary \sigma-ring) which contains every subset of every set in the ring, as well as being closed under countable union and set subtraction.
- PROBLEM: Outer measures are only subadditive not additive so they're not really measures. Make sure this weakness is demonstrated.
- We need to consider only the sets that have the property of dividing up every other set in the hereditary sigma-ring additively.
- We then show this new structure is a ring
- We then show this new structure is a \sigma-ring
- MEASURE (\mu) - The restriction of the outer-measure, \mu^*, \mu to this \sigma-ring is a measure, a pre-measure but on a \sigma-ring (instead of just ring)
- Show \mu is countably additive
We have now constructed a measure on a \sigma-ring, \mu from a pre-measure on a ring, \bar{\mu}
Remaining steps
- Show that \sigma_R(\mathcal{R}) (the sigma-ring generated by) is inside the \sigma-ring constructed from the outer-measure.
- Conclude that the sets in \mathcal{R} are in this new ring (trivial/definition) and the job is done, we have constructed a measure on \sigma_R(\mathcal{R})
Remaining problems
If \cdot is some arbitrary elements of the powerset (so \cdot\subseteq\mathcal{P}(X)) what letter to use, for example, f:\mathcal{A}\rightarrow\text{whatever} suggests an algebra in place. What letter to use for "just an arbitrary collection of subsets" eg for use on additive set function
Symbols and terminology
| Symbols of: | |
| Measure Theory | |
| (Conventions established on this site) Order of introduction | |
| Systems of sets Collections of subsets of X | |
|---|---|
| \mathcal{R} | Ring of sets |
| \mathcal{A} | Algebra of sets |
| (UNDECIDED) | Arbitrary collection of subsets |
| \mathcal{S} | "Measurable" sets of the Outer-measure |
| Measures | |
| \bar{\mu}:\mathcal{R}\rightarrow\mathbb{R}_{\ge0}\cup\{+\infty\} | Pre-measure |
| \mu^*:\mathcal{P}(X)\rightarrow\mathbb{R}_{\ge0}\cup\{+\infty\} | Outer-measure |
| \tilde{\mu}:\mathcal{S}\rightarrow\mathbb{R}_{\ge0}\cup\{+\infty\} | Measure induced by the outer-measure |
| \mu:\sigma_R(\mathcal{R})\rightarrow\mathbb{R}_{\ge0}\cup\{+\infty\} | measure induced on the sigma ring generated by |
- \mathcal{R} - Ring of sets - basically as it currently is
- \mathcal{A} - Mention Algebra of sets
- \bar{\mu}:\mathcal{R}\rightarrow\mathbb{R}_{\ge0}\cup\{+\infty\} (positive) Pre-measure - use the symbol \bar{\mu} instead of \mu
- \mu^*:\mathcal{P}(X)\rightarrow\mathbb{R}_{\ge0}\cup\{+\infty\} - outer-measure
- \mathcal{S} for the "outer-measurable sets" (and discussion of definition), proof is ring, proof is \sigma-ring
- \tilde{\mu}:\mathcal{S}\rightarrow\mathbb{R}_{\ge0}\cup\{+\infty\} - induced measure on \mathcal{S} (if needed)
- \mu:\sigma_R(\mathcal{R}):\sigma_R(\mathcal{R})\rightarrow\mathbb{R}_{\ge0}\cup\{+\infty\} - induced measure on the generated sigma ring.
