Regularity theorem for Lebesgue measure
In mathematics, the regularity theorem for Lebesgue measure is a result in measure theory that states that Lebesgue measure on the real line is a regular measure. Informally speaking, this means that every Lebesgue-measurable subset of the real line is "approximately open" and "approximately closed".
Statement of the theorem
Lebesgue measure on the real line, R, is a regular measure. That is, for all Lebesgue-measurable subsets A of R, and ε > 0, there exist subsets C and U of R such that
- C is closed; and
- U is open; and
- C ⊆ A ⊆ U; and
- the Lebesgue measure of U \ C is strictly less than ε.
Moreover, if A has finite Lebesgue measure, then C can be chosen to be compact (i.e. – by the Heine–Borel theorem – closed and bounded).
Corollary: the structure of Lebesgue measurable sets
If A is a Lebesgue measurable subset of R, then there exists a Borel set B and a null set N such that A is the symmetric difference of B and N:
gollark: I doubt the rich are very good food sources.
gollark: Initiating anti-duct-taping lasers.
gollark: Y̯̰̘o҉̺͚͇ư͖̭r̞͖͝ ̨̯̙”̖͖̰d͡ụ̶c̷̮͙t̳ ̵t̮̬̙á̺̦p̧͎͚e̴̗”̶ ̝̲ͅs̢͍͙o̜̯̤u̳̗n͉͎̠d̫s̖̥͍ ̹̰̫v̝̥͝e̶̗̲r̻͍̫y̶̯̫ ͞d̜̦͓úc̡̠̘ṯ̫̘-̣̥͟t̻̬͠a̫͟p̸̺̤e͙͖-̹̞̟y.͎̹̤
gollark: ˙pɹɐʍʞɔɐq ɹo pɹɐʍɹoɟ pᴉlɐʌ ʎllɐɔᴉʇɐɯɯɐɹƃ s,ʇɐɥʇ ʞuᴉɥʇ ʇ,uop I
gollark: I mean, if you do nothing about it, sure?
See also
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