Difference between revisions of "Set subtraction"
From Maths
m |
m (Adding to measure theory because useful there, adding relative complement and fleshing out) |
||
Line 1: | Line 1: | ||
+ | {{Stub page|Cleanup and further expansion}} | ||
+ | {{Requires references}} | ||
==Definition== | ==Definition== | ||
− | Given two sets, {{M|A}} and {{M|B}} we define ''set subtraction'' as follows: | + | Given two sets, {{M|A}} and {{M|B}} we define ''set subtraction'' ({{AKA}}: ''relative complement''{{rMTH}}) as follows: |
* {{M|1=A-B=\{x\in A\vert x\notin B\} }} | * {{M|1=A-B=\{x\in A\vert x\notin B\} }} | ||
− | === | + | ===Alternative forms=== |
{{Begin Inline Theorem}} | {{Begin Inline Theorem}} | ||
* {{M|1=A-B=(A^c\cup B)^c}} | * {{M|1=A-B=(A^c\cup B)^c}} | ||
{{Begin Inline Proof}} | {{Begin Inline Proof}} | ||
− | {{ | + | {{Requires proof|Be bothered to do this}} |
{{End Proof}}{{End Theorem}} | {{End Proof}}{{End Theorem}} | ||
− | == | + | ==Terminology== |
− | * Relative complement | + | * '''Relative complement'''<ref name="MTH"/> |
− | ** This comes from the | + | ** This comes from the idea of a [[complement]] of a subset of {{M|X}}, say {{M|A}} being just {{M|X-A}}, so if we have {{M|A,B\in\mathcal{P}(X)}} then {{M|A-B}} can be thought of as the complement of {{M|B}} if you consider it relative (to be in) {{M|A}}. |
==Notations== | ==Notations== | ||
Other notations include: | Other notations include: | ||
Line 30: | Line 32: | ||
==References== | ==References== | ||
<references/> | <references/> | ||
− | {{ | + | {{Set operations navbox}} |
{{Definition|Set Theory}} | {{Definition|Set Theory}} | ||
{{Theorem Of|Set Theory}} | {{Theorem Of|Set Theory}} | ||
+ | [[Category:Set operations]] |
Revision as of 00:44, 21 March 2016
(Unknown grade)
This page is a stub
This page is a stub, so it contains little or minimal information and is on a to-do list for being expanded.The message provided is:
Cleanup and further expansion
(Unknown grade)
This page requires references, it is on a to-do list for being expanded with them.
Please note that this does not mean the content is unreliable, it just means that the author of the page doesn't have a book to hand, or remember the book to find it, which would have been a suitable reference.
Contents
Definition
Given two sets, [ilmath]A[/ilmath] and [ilmath]B[/ilmath] we define set subtraction (AKA: relative complement[1]) as follows:
- [ilmath]A-B=\{x\in A\vert x\notin B\}[/ilmath]
Alternative forms
- [ilmath]A-B=(A^c\cup B)^c[/ilmath]
(Unknown grade)
This page requires one or more proofs to be filled in, it is on a to-do list for being expanded with them.
Please note that this does not mean the content is unreliable. Unless there are any caveats mentioned below the statement comes from a reliable source. As always, Warnings and limitations will be clearly shown and possibly highlighted if very important (see template:Caution et al).
The message provided is:
The message provided is:
Be bothered to do this
Terminology
- Relative complement[1]
- This comes from the idea of a complement of a subset of [ilmath]X[/ilmath], say [ilmath]A[/ilmath] being just [ilmath]X-A[/ilmath], so if we have [ilmath]A,B\in\mathcal{P}(X)[/ilmath] then [ilmath]A-B[/ilmath] can be thought of as the complement of [ilmath]B[/ilmath] if you consider it relative (to be in) [ilmath]A[/ilmath].
Notations
Other notations include:
- [ilmath]A\setminus B[/ilmath]
Trivial expressions for set subtraction
Claim: [ilmath](A-B)-C=A-(B\cup C)[/ilmath]
Proof:
- Note that [ilmath]A-B=(A^c\cup B)^c[/ilmath] so [ilmath](A-B)-C = ((A-B)^c\cup B)^c =(((A^c\cup B)^c)^c\cup C)^c[/ilmath]
- But: [ilmath](A^c)^c=A[/ilmath] so:
- [ilmath](A-B)-C=(A^c\cup B\cup C)^c=(A^c\cup(B\cup C))^c=A-(B\cup C)[/ilmath]
- But: [ilmath](A^c)^c=A[/ilmath] so:
TODO: Make this proof neat
See also
References
|
Categories:
- Stub pages
- Pages requiring references
- Pages requiring references of unknown grade
- Pages requiring proofs
- Pages requiring proofs of unknown grade
- Todo
- Definitions
- Set Theory Definitions
- Set Theory
- Theorems
- Theorems, lemmas and corollaries
- Set Theory Theorems
- Set Theory Theorems, lemmas and corollaries
- Set operations