Difference between revisions of "F-algebra"
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| − | + | A real [[Vector space|vector space]] $ A $ | |
| + | that is simultaneously a [[Lattice|lattice]] is called a vector lattice (or [[Riesz space|Riesz space]]) whenever $ x \leq y $( | ||
| + | $ \leq $ | ||
| + | is the lattice order) implies $ x + z \leq y + z $ | ||
| + | for all $ z \in A $ | ||
| + | and $ ax \leq ay $ | ||
| + | for all positive real numbers $ a $. | ||
| + | If $ A $ | ||
| + | is also an [[Algebra|algebra]] and $ zx \leq yz $ | ||
| + | and $ xz \leq yz $ | ||
| + | for all $ z \in A ^ {+} $, | ||
| + | the positive cone of $ A $, | ||
| + | then $ A $ | ||
| + | is called an $ l $- | ||
| + | algebra (a lattice-ordered algebra, Riesz algebra). | ||
| + | |||
| + | A Riesz algebra $ A $ | ||
| + | is called an $ f $- | ||
| + | algebra ( $ f $ | ||
| + | for "function" ) whenever | ||
| + | |||
| + | $$ | ||
| + | \inf ( x,y ) = 0 \Rightarrow \inf ( zx,y ) = \inf ( xz,y ) = 0 , \forall z \in A ^ {+} . | ||
| + | $$ | ||
This notion was introduced by G. Birkhoff and R.S. Pierce in 1956. | This notion was introduced by G. Birkhoff and R.S. Pierce in 1956. | ||
| − | An important example of an | + | An important example of an $ f $- |
| + | algebra is $ A = C ( X ) $, | ||
| + | the space of continuous functions (cf. [[Continuous functions, space of|Continuous functions, space of]]) on some [[Topological space|topological space]] $ X $. | ||
| + | Other examples are spaces of Baire functions, measurable functions and essentially bounded functions. $ f $- | ||
| + | Algebras play an important role in operator theory. The second commutant of a commuting subset of bounded Hermitian operators on some Hilbert space is an $ f $- | ||
| + | algebra. A [[Linear operator|linear operator]] $ T $ | ||
| + | on some vector lattice $ A $ | ||
| + | is called an orthomorphism whenever $ T $ | ||
| + | is the difference of two positive orthomorphisms; a positive orthomorphism $ S $ | ||
| + | on $ A $ | ||
| + | leaves the positive cone of $ A $ | ||
| + | invariant and satisfies $ \inf ( Sx,y ) = 0 $ | ||
| + | whenever $ \inf ( x,y ) = 0 $. | ||
| + | The space $ { \mathop{\rm Orth} } ( A ) $ | ||
| + | of all orthomorphisms of $ A $ | ||
| + | is an important example of an $ f $- | ||
| + | algebra in the theory of vector lattices. | ||
| − | A vector lattice | + | A vector lattice $ A $ |
| + | is termed Archimedean if $ 0 \leq nx \leq y $( | ||
| + | $ n = 1,2, \dots $) | ||
| + | implies $ x = 0 $. | ||
| + | Archimedean $ f $- | ||
| + | algebras are automatically commutative and associative. An Archimedean $ f $- | ||
| + | algebra with unit element is semi-prime (i.e., the only nilpotent element is $ 0 $). | ||
| + | The latter two properties are nice examples of the interplay between order properties and algebraic properties in an $ f $- | ||
| + | algebra. Many properties of $ C ( X ) $ | ||
| + | are inherited by an $ f $- | ||
| + | algebra $ A $ | ||
| + | with a unit element (under some additional completeness condition), such as the existence of the square root of a positive element (if $ x \in A ^ {+} $, | ||
| + | then there exists a unique $ y \in A ^ {+} $ | ||
| + | such that $ y ^ {( 2 ) } = x $) | ||
| + | and the existence of an inverse: if $ e $ | ||
| + | is the unit element of $ A $ | ||
| + | and $ e \leq x $, | ||
| + | then $ x ^ {- 1 } $ | ||
| + | exists in $ A $. | ||
====References==== | ====References==== | ||
<table><TR><TD valign="top">[a1]</TD> <TD valign="top"> G. Birkhoff, R.S. Pierce, "Lattice-ordered rings" ''An. Acad. Brasil. Ci.'' , '''28''' (1956) pp. 41–69</TD></TR><TR><TD valign="top">[a2]</TD> <TD valign="top"> A.C. Zaanen, "Riesz spaces" , '''II''' , North-Holland (1983)</TD></TR></table> | <table><TR><TD valign="top">[a1]</TD> <TD valign="top"> G. Birkhoff, R.S. Pierce, "Lattice-ordered rings" ''An. Acad. Brasil. Ci.'' , '''28''' (1956) pp. 41–69</TD></TR><TR><TD valign="top">[a2]</TD> <TD valign="top"> A.C. Zaanen, "Riesz spaces" , '''II''' , North-Holland (1983)</TD></TR></table> | ||
Latest revision as of 19:38, 5 June 2020
A real vector space $ A $
that is simultaneously a lattice is called a vector lattice (or Riesz space) whenever $ x \leq y $(
$ \leq $
is the lattice order) implies $ x + z \leq y + z $
for all $ z \in A $
and $ ax \leq ay $
for all positive real numbers $ a $.
If $ A $
is also an algebra and $ zx \leq yz $
and $ xz \leq yz $
for all $ z \in A ^ {+} $,
the positive cone of $ A $,
then $ A $
is called an $ l $-
algebra (a lattice-ordered algebra, Riesz algebra).
A Riesz algebra $ A $ is called an $ f $- algebra ( $ f $ for "function" ) whenever
$$ \inf ( x,y ) = 0 \Rightarrow \inf ( zx,y ) = \inf ( xz,y ) = 0 , \forall z \in A ^ {+} . $$
This notion was introduced by G. Birkhoff and R.S. Pierce in 1956.
An important example of an $ f $- algebra is $ A = C ( X ) $, the space of continuous functions (cf. Continuous functions, space of) on some topological space $ X $. Other examples are spaces of Baire functions, measurable functions and essentially bounded functions. $ f $- Algebras play an important role in operator theory. The second commutant of a commuting subset of bounded Hermitian operators on some Hilbert space is an $ f $- algebra. A linear operator $ T $ on some vector lattice $ A $ is called an orthomorphism whenever $ T $ is the difference of two positive orthomorphisms; a positive orthomorphism $ S $ on $ A $ leaves the positive cone of $ A $ invariant and satisfies $ \inf ( Sx,y ) = 0 $ whenever $ \inf ( x,y ) = 0 $. The space $ { \mathop{\rm Orth} } ( A ) $ of all orthomorphisms of $ A $ is an important example of an $ f $- algebra in the theory of vector lattices.
A vector lattice $ A $ is termed Archimedean if $ 0 \leq nx \leq y $( $ n = 1,2, \dots $) implies $ x = 0 $. Archimedean $ f $- algebras are automatically commutative and associative. An Archimedean $ f $- algebra with unit element is semi-prime (i.e., the only nilpotent element is $ 0 $). The latter two properties are nice examples of the interplay between order properties and algebraic properties in an $ f $- algebra. Many properties of $ C ( X ) $ are inherited by an $ f $- algebra $ A $ with a unit element (under some additional completeness condition), such as the existence of the square root of a positive element (if $ x \in A ^ {+} $, then there exists a unique $ y \in A ^ {+} $ such that $ y ^ {( 2 ) } = x $) and the existence of an inverse: if $ e $ is the unit element of $ A $ and $ e \leq x $, then $ x ^ {- 1 } $ exists in $ A $.
References
| [a1] | G. Birkhoff, R.S. Pierce, "Lattice-ordered rings" An. Acad. Brasil. Ci. , 28 (1956) pp. 41–69 |
| [a2] | A.C. Zaanen, "Riesz spaces" , II , North-Holland (1983) |
How to Cite This Entry:
F-algebra. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=F-algebra&oldid=46895
F-algebra. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=F-algebra&oldid=46895
This article was adapted from an original article by C.B. Huijsmans (originator), which appeared in Encyclopedia of Mathematics - ISBN 1402006098. See original article