In mathematics, a nonempty collection of sets is called a 𝜎-ring (pronounced sigma-ring) if it is closed under countable union and relative complementation.
Formal definition
editLet be a nonempty collection of sets. Then is a 𝜎-ring if:
- Closed under countable unions: if for all
- Closed under relative complementation: if
Properties
editThese two properties imply: whenever are elements of
This is because
Every 𝜎-ring is a δ-ring but there exist δ-rings that are not 𝜎-rings.
Similar concepts
editIf the first property is weakened to closure under finite union (that is, whenever ) but not countable union, then is a ring but not a 𝜎-ring.
Uses
edit𝜎-rings can be used instead of 𝜎-fields (𝜎-algebras) in the development of measure and integration theory, if one does not wish to require that the universal set be measurable. Every 𝜎-field is also a 𝜎-ring, but a 𝜎-ring need not be a 𝜎-field.
A 𝜎-ring that is a collection of subsets of induces a 𝜎-field for Define Then is a 𝜎-field over the set - to check closure under countable union, recall a -ring is closed under countable intersections. In fact is the minimal 𝜎-field containing since it must be contained in every 𝜎-field containing
See also
edit- δ-ring – Ring closed under countable intersections
- Field of sets – Algebraic concept in measure theory, also referred to as an algebra of sets
- Join (sigma algebra) – Algebraic structure of set algebra
- 𝜆-system (Dynkin system) – Family closed under complements and countable disjoint unions
- Measurable function – Kind of mathematical function
- Monotone class – theorem
- π-system – Family of sets closed under intersection
- Ring of sets – Family closed under unions and relative complements
- Sample space – Set of all possible outcomes or results of a statistical trial or experiment
- 𝜎 additivity – Mapping function
- σ-algebra – Algebraic structure of set algebra
- 𝜎-ideal – Family closed under subsets and countable unions
References
edit- Walter Rudin, 1976. Principles of Mathematical Analysis, 3rd. ed. McGraw-Hill. Final chapter uses 𝜎-rings in development of Lebesgue theory.
Families of sets over | ||||||||||
---|---|---|---|---|---|---|---|---|---|---|
Is necessarily true of or, is closed under: |
Directed by |
F.I.P. | ||||||||
π-system | ||||||||||
Semiring | Never | |||||||||
Semialgebra (Semifield) | Never | |||||||||
Monotone class | only if | only if | ||||||||
𝜆-system (Dynkin System) | only if |
only if or they are disjoint |
Never | |||||||
Ring (Order theory) | ||||||||||
Ring (Measure theory) | Never | |||||||||
δ-Ring | Never | |||||||||
𝜎-Ring | Never | |||||||||
Algebra (Field) | Never | |||||||||
𝜎-Algebra (𝜎-Field) | Never | |||||||||
Dual ideal | ||||||||||
Filter | Never | Never | ||||||||
Prefilter (Filter base) | Never | Never | ||||||||
Filter subbase | Never | Never | ||||||||
Open Topology | (even arbitrary ) |
Never | ||||||||
Closed Topology | (even arbitrary ) |
Never | ||||||||
Is necessarily true of or, is closed under: |
directed downward |
finite intersections |
finite unions |
relative complements |
complements in |
countable intersections |
countable unions |
contains | contains | Finite Intersection Property |
Additionally, a semiring is a π-system where every complement is equal to a finite disjoint union of sets in |