Difference between revisions of "Dedekind completion"
From Encyclopedia of Mathematics
(Importing text file) |
Ulf Rehmann (talk | contribs) m (tex encoded by computer) |
||
| Line 1: | Line 1: | ||
| + | <!-- | ||
| + | d1100501.png | ||
| + | $#A+1 = 43 n = 0 | ||
| + | $#C+1 = 43 : ~/encyclopedia/old_files/data/D110/D.1100050 Dedekind completion | ||
| + | Automatically converted into TeX, above some diagnostics. | ||
| + | Please remove this comment and the {{TEX|auto}} line below, | ||
| + | if TeX found to be correct. | ||
| + | --> | ||
| + | |||
| + | {{TEX|auto}} | ||
| + | {{TEX|done}} | ||
| + | |||
''of a Riesz space'' | ''of a Riesz space'' | ||
A [[Riesz space|Riesz space]] is called Dedekind complete if every non-empty subset that is bounded from below (respectively, above) has an infimum (respectively, supremum). A Dedekind-complete Riesz space is automatically Archimedean. Hence, so are its Riesz subspaces. | A [[Riesz space|Riesz space]] is called Dedekind complete if every non-empty subset that is bounded from below (respectively, above) has an infimum (respectively, supremum). A Dedekind-complete Riesz space is automatically Archimedean. Hence, so are its Riesz subspaces. | ||
| − | Given an Archimedean Riesz space | + | Given an Archimedean Riesz space $ L $, |
| + | a Dedekind completion of $ L $ | ||
| + | is a pair $ ( M,T ) $ | ||
| + | where $ M $ | ||
| + | is a Riesz space and $ T : L \rightarrow M $ | ||
| + | is a mapping such that | ||
| − | 1) | + | 1) $ M $ |
| + | is Dedekind complete; | ||
| − | 2) | + | 2) $ T $ |
| + | is a Riesz isomorphism of $ L $ | ||
| + | onto a Riesz subspace $ T ( L ) $ | ||
| + | of $ M $; | ||
| − | 3) as a mapping | + | 3) as a mapping $ L \rightarrow M $, |
| + | $ T $ | ||
| + | is normal, i.e., it preserves arbitrary suprema and infima; | ||
| − | 4) for all | + | 4) for all $ a \in M $, |
| − | + | $$ | |
| + | a = \sup \left \{ {x \in T ( L ) } : {x \leq a } \right \} = \inf \left \{ {x \in T ( L ) } : {x \geq a } \right \} . | ||
| + | $$ | ||
| − | Every Archimedean Riesz space | + | Every Archimedean Riesz space $ L $ |
| + | has a Dedekind completion, whose underlying [[Partially ordered set|partially ordered set]] can be obtained from the MacNeille completion (cf. [[Completion, MacNeille (of a partially ordered set)|Completion, MacNeille (of a partially ordered set)]]) of $ L $ | ||
| + | by removing its largest and smallest elements. The Dedekind completion is unique in the following sense. If $ ( M _ {1} ,T _ {1} ) $ | ||
| + | and $ ( M _ {2} ,T _ {2} ) $ | ||
| + | are Dedekind completions of $ L $, | ||
| + | then there exists a unique Riesz isomorphism $ S $ | ||
| + | of $ M _ {1} $ | ||
| + | onto $ M _ {2} $ | ||
| + | with $ T _ {2} = S \circ T _ {1} $. | ||
| + | More generally, if $ ( M,T ) $ | ||
| + | is a Dedekind completion of $ L $, | ||
| + | then every normal Riesz homomorphism of $ L $ | ||
| + | into any Dedekind-complete Riesz space $ K $ | ||
| + | can uniquely be extended to a normal Riesz homomorphism $ M \rightarrow K $. | ||
| − | The Riesz spaces | + | The Riesz spaces $ L _ {p} ( \mu ) $( |
| + | $ 1 \leq p < \infty $) | ||
| + | are Dedekind complete; so is $ L _ \infty ( \mu ) $ | ||
| + | if $ \mu $ | ||
| + | is $ \sigma $- | ||
| + | finite. The space $ C ( X ) $( | ||
| + | $ X $ | ||
| + | a compact [[Hausdorff space|Hausdorff space]]) is Dedekind complete if and only if $ X $ | ||
| + | is extremally disconnected (cf. [[Extremally-disconnected space|Extremally-disconnected space]]). There are few non-trivial instances of Riesz spaces whose Dedekind completions are to some extent "understood" . The Dedekind completion of the space $ c $ | ||
| + | of all converging sequences is $ l _ \infty $. | ||
| + | That of $ C ( X ) $ | ||
| + | is the quotient $ B ( X ) /N $, | ||
| + | where $ B ( X ) $ | ||
| + | is the space of all bounded Borel functions and $ N $ | ||
| + | is the ideal of all functions that vanish off meager sets (cf. [[Category of a set|Category of a set]]). (In either case, the mapping $ T : L \rightarrow M $ | ||
| + | is obvious.) | ||
====References==== | ====References==== | ||
<table><TR><TD valign="top">[a1]</TD> <TD valign="top"> E. de Jonge, A. van Rooij, "Introduction to Riesz spaces" , ''Tracts'' , '''8''' , Math. Centre, Amsterdam (1977)</TD></TR><TR><TD valign="top">[a2]</TD> <TD valign="top"> W. Luxemburg, A.C. Zaanen, "Riesz spaces" , '''I''' , North-Holland (1974)</TD></TR><TR><TD valign="top">[a3]</TD> <TD valign="top"> B.Z. Vulikh, "Introduction to the theory of partially ordered spaces" , Wolters–Noordhoff (1967) (In Russian)</TD></TR></table> | <table><TR><TD valign="top">[a1]</TD> <TD valign="top"> E. de Jonge, A. van Rooij, "Introduction to Riesz spaces" , ''Tracts'' , '''8''' , Math. Centre, Amsterdam (1977)</TD></TR><TR><TD valign="top">[a2]</TD> <TD valign="top"> W. Luxemburg, A.C. Zaanen, "Riesz spaces" , '''I''' , North-Holland (1974)</TD></TR><TR><TD valign="top">[a3]</TD> <TD valign="top"> B.Z. Vulikh, "Introduction to the theory of partially ordered spaces" , Wolters–Noordhoff (1967) (In Russian)</TD></TR></table> | ||
Latest revision as of 17:32, 5 June 2020
of a Riesz space
A Riesz space is called Dedekind complete if every non-empty subset that is bounded from below (respectively, above) has an infimum (respectively, supremum). A Dedekind-complete Riesz space is automatically Archimedean. Hence, so are its Riesz subspaces.
Given an Archimedean Riesz space $ L $, a Dedekind completion of $ L $ is a pair $ ( M,T ) $ where $ M $ is a Riesz space and $ T : L \rightarrow M $ is a mapping such that
1) $ M $ is Dedekind complete;
2) $ T $ is a Riesz isomorphism of $ L $ onto a Riesz subspace $ T ( L ) $ of $ M $;
3) as a mapping $ L \rightarrow M $, $ T $ is normal, i.e., it preserves arbitrary suprema and infima;
4) for all $ a \in M $,
$$ a = \sup \left \{ {x \in T ( L ) } : {x \leq a } \right \} = \inf \left \{ {x \in T ( L ) } : {x \geq a } \right \} . $$
Every Archimedean Riesz space $ L $ has a Dedekind completion, whose underlying partially ordered set can be obtained from the MacNeille completion (cf. Completion, MacNeille (of a partially ordered set)) of $ L $ by removing its largest and smallest elements. The Dedekind completion is unique in the following sense. If $ ( M _ {1} ,T _ {1} ) $ and $ ( M _ {2} ,T _ {2} ) $ are Dedekind completions of $ L $, then there exists a unique Riesz isomorphism $ S $ of $ M _ {1} $ onto $ M _ {2} $ with $ T _ {2} = S \circ T _ {1} $. More generally, if $ ( M,T ) $ is a Dedekind completion of $ L $, then every normal Riesz homomorphism of $ L $ into any Dedekind-complete Riesz space $ K $ can uniquely be extended to a normal Riesz homomorphism $ M \rightarrow K $.
The Riesz spaces $ L _ {p} ( \mu ) $( $ 1 \leq p < \infty $) are Dedekind complete; so is $ L _ \infty ( \mu ) $ if $ \mu $ is $ \sigma $- finite. The space $ C ( X ) $( $ X $ a compact Hausdorff space) is Dedekind complete if and only if $ X $ is extremally disconnected (cf. Extremally-disconnected space). There are few non-trivial instances of Riesz spaces whose Dedekind completions are to some extent "understood" . The Dedekind completion of the space $ c $ of all converging sequences is $ l _ \infty $. That of $ C ( X ) $ is the quotient $ B ( X ) /N $, where $ B ( X ) $ is the space of all bounded Borel functions and $ N $ is the ideal of all functions that vanish off meager sets (cf. Category of a set). (In either case, the mapping $ T : L \rightarrow M $ is obvious.)
References
| [a1] | E. de Jonge, A. van Rooij, "Introduction to Riesz spaces" , Tracts , 8 , Math. Centre, Amsterdam (1977) |
| [a2] | W. Luxemburg, A.C. Zaanen, "Riesz spaces" , I , North-Holland (1974) |
| [a3] | B.Z. Vulikh, "Introduction to the theory of partially ordered spaces" , Wolters–Noordhoff (1967) (In Russian) |
How to Cite This Entry:
Dedekind completion. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Dedekind_completion&oldid=46597
Dedekind completion. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Dedekind_completion&oldid=46597
This article was adapted from an original article by A.C.M. van Rooy (originator), which appeared in Encyclopedia of Mathematics - ISBN 1402006098. See original article