Difference between revisions of "Chain space"
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An [[Incidence system|incidence system]] to axiomatically describe chain geometries (cf. [[Chain geometry|Chain geometry]]). | An [[Incidence system|incidence system]] to axiomatically describe chain geometries (cf. [[Chain geometry|Chain geometry]]). | ||
− | A weak chain space is an incidence system | + | A weak chain space is an incidence system $ {\mathcal I} = ( P, \mathfrak C,I ) $ |
+ | satisfying the three conditions below. Here, the elements of $ \mathfrak C $ | ||
+ | are called chains and two different points (i.e., elements of $ P $) | ||
+ | are called distant if they are incident with a common chain. | ||
i) any three pairwise distant points are contained in exactly one chain; | i) any three pairwise distant points are contained in exactly one chain; | ||
Line 9: | Line 24: | ||
iii) any point lies in at least one chain. | iii) any point lies in at least one chain. | ||
− | For a point | + | For a point $ p $, |
+ | let $ D _ {p} $ | ||
+ | be the set of all points distant to $ p $ | ||
+ | and let $ ( p ) = \{ {C \in \mathfrak C } : {pIC } \} $. | ||
+ | Then the incidence system $ {\mathcal I} _ {p} = ( D _ {p} , ( p ) ,I ) $ | ||
+ | is called the residual space of $ {\mathcal I} $ | ||
+ | at $ p $. | ||
− | A partial parallel structure | + | A partial parallel structure $ ( P, \mathfrak B,I, \| ) $ |
+ | is an incidence system $ ( P, \mathfrak B,I ) $ | ||
+ | together with an [[Equivalence|equivalence]] relation $ \| $ | ||
+ | on $ \mathfrak B $ | ||
+ | satisfying the two conditions below. Here, the elements of $ \mathfrak B $ | ||
+ | are called lines. | ||
a) two different points are incident with at most one line; | a) two different points are incident with at most one line; | ||
− | b) for a line | + | b) for a line $ L $ |
+ | and point $ p $, | ||
+ | there is exactly one line, $ L ^ \prime $, | ||
+ | incident with $ p $ | ||
+ | and such that $ L \| L ^ \prime $. | ||
+ | Condition b) is the Euclid parallel axiom. | ||
− | A partial parallel structure | + | A partial parallel structure $ ( P, \mathfrak B,I, \| ) $ |
+ | is called a partial affine space if there is an [[Affine space|affine space]] $ {\mathcal A} $ | ||
+ | such that $ P $ | ||
+ | is the set of points of $ {\mathcal A} $, | ||
+ | $ \mathfrak B $ | ||
+ | is the set of straight lines of $ {\mathcal A} $ | ||
+ | and $ \| $ | ||
+ | is the natural parallelism on $ {\mathcal A} $. | ||
A weak chain space is called a chain space if all residual spaces of it are partial affine spaces. | A weak chain space is called a chain space if all residual spaces of it are partial affine spaces. | ||
Line 23: | Line 61: | ||
Every proper [[Chain geometry|chain geometry]] is a chain space. Conversely, the chain spaces that are proper chain geometries can be characterized by suitable automorphism groups [[#References|[a1]]]. | Every proper [[Chain geometry|chain geometry]] is a chain space. Conversely, the chain spaces that are proper chain geometries can be characterized by suitable automorphism groups [[#References|[a1]]]. | ||
− | A contact space | + | A contact space $ {\mathcal C} = ( P, \mathfrak B,I, ( \rho _ {p} ) _ {p \in P } ) $ |
+ | is a weak chain space $ ( P, \mathfrak B,I ) $ | ||
+ | together with a family $ ( \rho _ {p} ) _ {p \in P } $, | ||
+ | where $ \rho _ {p} $ | ||
+ | is an equivalence relation on $ ( p ) $ | ||
+ | with the following properties: | ||
− | 1) if | + | 1) if $ C \rho _ {p} C ^ \prime $, |
+ | then $ p $ | ||
+ | is the only point common to $ C $ | ||
+ | and $ C ^ \prime $; | ||
− | 2) if | + | 2) if $ pIC $ |
+ | and $ q $ | ||
+ | is a point distant to $ p $, | ||
+ | then there is a unique chain $ C ^ \prime $ | ||
+ | incident with $ p $ | ||
+ | and $ q $ | ||
+ | for which $ C \rho _ {p} C ^ \prime $. | ||
− | Clearly, for a contact space | + | Clearly, for a contact space $ ( P, \mathfrak B,I, ( \rho _ {p} ) _ {p \in P } ) $ |
+ | any residual space of the incidence system $ ( P, \mathfrak B,I ) $ | ||
+ | gives rise to a partial parallel structure $ ( D _ {p} , ( p ) ,I, \rho _ {p} ) $. | ||
+ | Conversely, any chain space $ {\mathcal I} $ | ||
+ | is a contact space (taking for $ \rho _ {p} $ | ||
+ | the natural parallelism of the affine space underlying $ {\mathcal I} $). | ||
+ | One can characterize the contact spaces that are chain spaces by certain configurations together with richness conditions [[#References|[a3]]]. | ||
− | An affine chain space | + | An affine chain space $ \mathfrak A = ( P, \mathfrak C,I ) $ |
+ | is a contact space, where $ P $ | ||
+ | is the point set of an affine space $ {\mathcal A} $. | ||
+ | The elements of $ \mathfrak C $ | ||
+ | are called affine chains and are normal rational curves in $ {\mathcal A} $, | ||
+ | i.e., affine parts of curves which are a Veronese variety (cf. [[Veronese mapping|Veronese mapping]]). For the set $ \mathfrak L $ | ||
+ | of all affine chains that are straight lines, the structure $ ( P, \mathfrak L,I, \| ) $ | ||
+ | is a partial affine space. Affine chain spaces can be constructed by means of Jordan algebras [[#References|[a2]]] (cf. also [[Jordan algebra|Jordan algebra]]). | ||
− | A classical example is the quadric model of a chain space, constructed on a [[Quadric|quadric]] | + | A classical example is the quadric model of a chain space, constructed on a [[Quadric|quadric]] $ Q $ |
+ | by means of plane sections. Moreover, the [[Stereographic projection|stereographic projection]] from a simple point $ p $ | ||
+ | of $ Q $( | ||
+ | to a hyperplane different from the tangent plane of $ Q $ | ||
+ | at $ p $) | ||
+ | then gives rise to an affine chain space (cf. also [[Benz plane|Benz plane]]). | ||
====References==== | ====References==== | ||
<table><TR><TD valign="top">[a1]</TD> <TD valign="top"> A. Herzer, "Chain geometries" F. Buekenhout (ed.) , ''Handbook of Incidence Geometry'' , North-Holland (1995)</TD></TR><TR><TD valign="top">[a2]</TD> <TD valign="top"> A. Herzer, "Affine Kettengeometrien über Jordan-Algebren" ''Geom. Dedicata'' , '''59''' (1996) pp. 181–195</TD></TR><TR><TD valign="top">[a3]</TD> <TD valign="top"> S. Meuren, A. Herzer, "Ein Axiomsystem für partielle affine Räume" ''J. Geom.'' , '''50''' (1994) pp. 124–142</TD></TR></table> | <table><TR><TD valign="top">[a1]</TD> <TD valign="top"> A. Herzer, "Chain geometries" F. Buekenhout (ed.) , ''Handbook of Incidence Geometry'' , North-Holland (1995)</TD></TR><TR><TD valign="top">[a2]</TD> <TD valign="top"> A. Herzer, "Affine Kettengeometrien über Jordan-Algebren" ''Geom. Dedicata'' , '''59''' (1996) pp. 181–195</TD></TR><TR><TD valign="top">[a3]</TD> <TD valign="top"> S. Meuren, A. Herzer, "Ein Axiomsystem für partielle affine Räume" ''J. Geom.'' , '''50''' (1994) pp. 124–142</TD></TR></table> |
Latest revision as of 16:43, 4 June 2020
An incidence system to axiomatically describe chain geometries (cf. Chain geometry).
A weak chain space is an incidence system $ {\mathcal I} = ( P, \mathfrak C,I ) $ satisfying the three conditions below. Here, the elements of $ \mathfrak C $ are called chains and two different points (i.e., elements of $ P $) are called distant if they are incident with a common chain.
i) any three pairwise distant points are contained in exactly one chain;
ii) any chain contains at least three points;
iii) any point lies in at least one chain.
For a point $ p $, let $ D _ {p} $ be the set of all points distant to $ p $ and let $ ( p ) = \{ {C \in \mathfrak C } : {pIC } \} $. Then the incidence system $ {\mathcal I} _ {p} = ( D _ {p} , ( p ) ,I ) $ is called the residual space of $ {\mathcal I} $ at $ p $.
A partial parallel structure $ ( P, \mathfrak B,I, \| ) $ is an incidence system $ ( P, \mathfrak B,I ) $ together with an equivalence relation $ \| $ on $ \mathfrak B $ satisfying the two conditions below. Here, the elements of $ \mathfrak B $ are called lines.
a) two different points are incident with at most one line;
b) for a line $ L $ and point $ p $, there is exactly one line, $ L ^ \prime $, incident with $ p $ and such that $ L \| L ^ \prime $. Condition b) is the Euclid parallel axiom.
A partial parallel structure $ ( P, \mathfrak B,I, \| ) $ is called a partial affine space if there is an affine space $ {\mathcal A} $ such that $ P $ is the set of points of $ {\mathcal A} $, $ \mathfrak B $ is the set of straight lines of $ {\mathcal A} $ and $ \| $ is the natural parallelism on $ {\mathcal A} $.
A weak chain space is called a chain space if all residual spaces of it are partial affine spaces.
Every proper chain geometry is a chain space. Conversely, the chain spaces that are proper chain geometries can be characterized by suitable automorphism groups [a1].
A contact space $ {\mathcal C} = ( P, \mathfrak B,I, ( \rho _ {p} ) _ {p \in P } ) $ is a weak chain space $ ( P, \mathfrak B,I ) $ together with a family $ ( \rho _ {p} ) _ {p \in P } $, where $ \rho _ {p} $ is an equivalence relation on $ ( p ) $ with the following properties:
1) if $ C \rho _ {p} C ^ \prime $, then $ p $ is the only point common to $ C $ and $ C ^ \prime $;
2) if $ pIC $ and $ q $ is a point distant to $ p $, then there is a unique chain $ C ^ \prime $ incident with $ p $ and $ q $ for which $ C \rho _ {p} C ^ \prime $.
Clearly, for a contact space $ ( P, \mathfrak B,I, ( \rho _ {p} ) _ {p \in P } ) $ any residual space of the incidence system $ ( P, \mathfrak B,I ) $ gives rise to a partial parallel structure $ ( D _ {p} , ( p ) ,I, \rho _ {p} ) $. Conversely, any chain space $ {\mathcal I} $ is a contact space (taking for $ \rho _ {p} $ the natural parallelism of the affine space underlying $ {\mathcal I} $). One can characterize the contact spaces that are chain spaces by certain configurations together with richness conditions [a3].
An affine chain space $ \mathfrak A = ( P, \mathfrak C,I ) $ is a contact space, where $ P $ is the point set of an affine space $ {\mathcal A} $. The elements of $ \mathfrak C $ are called affine chains and are normal rational curves in $ {\mathcal A} $, i.e., affine parts of curves which are a Veronese variety (cf. Veronese mapping). For the set $ \mathfrak L $ of all affine chains that are straight lines, the structure $ ( P, \mathfrak L,I, \| ) $ is a partial affine space. Affine chain spaces can be constructed by means of Jordan algebras [a2] (cf. also Jordan algebra).
A classical example is the quadric model of a chain space, constructed on a quadric $ Q $ by means of plane sections. Moreover, the stereographic projection from a simple point $ p $ of $ Q $( to a hyperplane different from the tangent plane of $ Q $ at $ p $) then gives rise to an affine chain space (cf. also Benz plane).
References
[a1] | A. Herzer, "Chain geometries" F. Buekenhout (ed.) , Handbook of Incidence Geometry , North-Holland (1995) |
[a2] | A. Herzer, "Affine Kettengeometrien über Jordan-Algebren" Geom. Dedicata , 59 (1996) pp. 181–195 |
[a3] | S. Meuren, A. Herzer, "Ein Axiomsystem für partielle affine Räume" J. Geom. , 50 (1994) pp. 124–142 |
Chain space. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Chain_space&oldid=12810