Matroid: Difference between revisions
imported>Richard Pinch (new entry, just a stub, definitions, examples and reference) |
imported>Richard Pinch (added section Rank, reference Oxley) |
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* ''The exchange property'': if <math>A, B \in \mathcal{E}</math> with <math>|B| = |A| + 1</math> then there exists <math>x \in B \setminus A</math> such that <math>A \cup \{x\} \in \mathcal{E}</math>. | * ''The exchange property'': if <math>A, B \in \mathcal{E}</math> with <math>|B| = |A| + 1</math> then there exists <math>x \in B \setminus A</math> such that <math>A \cup \{x\} \in \mathcal{E}</math>. | ||
A ''basis'' in an independence structure is a maximal independent set. Any two bases have the same number of elements. | A ''basis'' in an independence structure is a maximal independent set. Any two bases have the same number of elements. A ''circuit'' is a minimal dependent set. Independence spaces can be defined in terms of their systems of bases or of their circuits. | ||
==Examples== | ==Examples== | ||
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* [[Affinely independent set]]s in an [[affine space]]; | * [[Affinely independent set]]s in an [[affine space]]; | ||
* [[Forest]]s in a [[Graph theory|graph]]. | * [[Forest]]s in a [[Graph theory|graph]]. | ||
==Rank== | |||
We define the '''rank''' ρ(''A'') of a subset ''A'' of ''E'' to be the maximum [[cardinality]] of an independent subset of ''A''. The rank satisfies the following | |||
:<math>0 \le \rho(A) \le |A| ;\,</math> | |||
:<math>A \subseteq B \Rightarrow \rho(A) \le \rho(B) ;\,</math> | |||
:<math>\rho(A) + \rho(B) \ge \rho(A\cap B) + \rho(A \cup B) .\,</math> | |||
The last of these is the ''submodular inequality''. | |||
A ''flat'' is a subset ''A'' of ''E'' such that the rank of ''A'' is strictly less than the rank of any proper [[superset]] of ''A''. | |||
==References== | ==References== | ||
* {{cite book | author=Victor Bryant | coauthors=Hazel Perfect | title=Independence Theory in Combinatorics | publisher=Chapman and Hall | year=1980 | isbn=0-412-22430-5 }} | * {{cite book | author=Victor Bryant | coauthors=Hazel Perfect | title=Independence Theory in Combinatorics | publisher=Chapman and Hall | year=1980 | isbn=0-412-22430-5 }} | ||
* {{cite book | author=James Oxley | title=Matroid theory | publisher=[[Oxford University Press]] | year=1992 | isbn =0-19-853563-5 }} |
Revision as of 01:34, 7 January 2009
In mathematics, an independence space is a structure that generalises the concept of linear and algebraic independence.
An independence structure on a set E is a family of subsets of E, called independent sets, with the properties
- is a downset, that is, ;
- The exchange property: if with then there exists such that .
A basis in an independence structure is a maximal independent set. Any two bases have the same number of elements. A circuit is a minimal dependent set. Independence spaces can be defined in terms of their systems of bases or of their circuits.
Examples
The following sets form independence structures:
- ;
- ;
- Linearly independent sets in a vector space;
- Algebraically independent sets in a field extension;
- Affinely independent sets in an affine space;
- Forests in a graph.
Rank
We define the rank ρ(A) of a subset A of E to be the maximum cardinality of an independent subset of A. The rank satisfies the following
The last of these is the submodular inequality.
A flat is a subset A of E such that the rank of A is strictly less than the rank of any proper superset of A.
References
- Victor Bryant; Hazel Perfect (1980). Independence Theory in Combinatorics. Chapman and Hall. ISBN 0-412-22430-5.
- James Oxley (1992). Matroid theory. Oxford University Press. ISBN 0-19-853563-5.