Difference between revisions of "Measure-preserving transformation"
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− | A [[Measurable mapping|measurable mapping]] | + | {{TEX|auto}} |
+ | {{TEX|done}} | ||
+ | |||
+ | ''of a [[Measure space|measure space]] $ ( X , \mathfrak A , \mu ) $.'' | ||
+ | |||
+ | {{MSC|28D05}} | ||
+ | |||
+ | [[Category:Measure-theoretic ergodic theory]] | ||
+ | |||
+ | A [[Measurable mapping|measurable mapping]] $ T : X \rightarrow X $ | ||
+ | such that $ \mu ( T ^ {-} 1 ( A) ) = \nu ( A) $ | ||
+ | for every $ A \in \mathfrak A $; | ||
+ | $ \mu $ | ||
+ | is called an invariant measure for $ T $. | ||
+ | A measurable mapping $ T : X \rightarrow Y $ | ||
+ | between measure spaces $ ( X , \mathfrak A , \mu ) $ | ||
+ | and $ ( Y , \mathfrak B , \nu ) $ | ||
+ | such that $ \mu ( T ^ {-} 1 ( B) ) = \nu ( B) $ | ||
+ | for every $ B \in \mathfrak B $ | ||
+ | is usually called a measure-preserving mapping. A surjective measure-preserving transformation $ T $ | ||
+ | of a measure space $ ( X , \mathfrak A , \mu ) $, | ||
+ | i.e., $ T $ | ||
+ | maps $ X $ | ||
+ | onto itself, is often called an endomorphism of $ ( X , \mathfrak A , \mu ) $; | ||
+ | an endomorphism which is bijective and whose inverse is also measure preserving is called an [[Automorphism|automorphism]] of $ ( X , \mathfrak A , \mu ) $. | ||
Measure-preserving transformations arise, for example, in the study of classical dynamical systems (cf. (measurable) [[Cascade|Cascade]]; [[Measurable flow|Measurable flow]]). In that case the transformation is first obtained as a continuous (or smooth) transformation of some, often compact, topological space (or manifold), and the existence of an invariant measure is proved. An example is Liouville's theorem for a [[Hamiltonian system|Hamiltonian system]] (cf. also [[Liouville theorems|Liouville theorems]]). | Measure-preserving transformations arise, for example, in the study of classical dynamical systems (cf. (measurable) [[Cascade|Cascade]]; [[Measurable flow|Measurable flow]]). In that case the transformation is first obtained as a continuous (or smooth) transformation of some, often compact, topological space (or manifold), and the existence of an invariant measure is proved. An example is Liouville's theorem for a [[Hamiltonian system|Hamiltonian system]] (cf. also [[Liouville theorems|Liouville theorems]]). | ||
For further information and references see [[Ergodic theory|Ergodic theory]]. | For further information and references see [[Ergodic theory|Ergodic theory]]. |
Latest revision as of 08:00, 6 June 2020
of a measure space $ ( X , \mathfrak A , \mu ) $.
2020 Mathematics Subject Classification: Primary: 28D05 [MSN][ZBL]
A measurable mapping $ T : X \rightarrow X $ such that $ \mu ( T ^ {-} 1 ( A) ) = \nu ( A) $ for every $ A \in \mathfrak A $; $ \mu $ is called an invariant measure for $ T $. A measurable mapping $ T : X \rightarrow Y $ between measure spaces $ ( X , \mathfrak A , \mu ) $ and $ ( Y , \mathfrak B , \nu ) $ such that $ \mu ( T ^ {-} 1 ( B) ) = \nu ( B) $ for every $ B \in \mathfrak B $ is usually called a measure-preserving mapping. A surjective measure-preserving transformation $ T $ of a measure space $ ( X , \mathfrak A , \mu ) $, i.e., $ T $ maps $ X $ onto itself, is often called an endomorphism of $ ( X , \mathfrak A , \mu ) $; an endomorphism which is bijective and whose inverse is also measure preserving is called an automorphism of $ ( X , \mathfrak A , \mu ) $.
Measure-preserving transformations arise, for example, in the study of classical dynamical systems (cf. (measurable) Cascade; Measurable flow). In that case the transformation is first obtained as a continuous (or smooth) transformation of some, often compact, topological space (or manifold), and the existence of an invariant measure is proved. An example is Liouville's theorem for a Hamiltonian system (cf. also Liouville theorems).
For further information and references see Ergodic theory.
Measure-preserving transformation. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Measure-preserving_transformation&oldid=15953