Difference between revisions of "Subprojective space"
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| − | + | One of the generalizations of spaces of constant curvature (of projective space). One defines a $ k $- | |
| + | fold [[Projective space|projective space]] with an [[Affine connection|affine connection]] and expresses its geodesic lines in some coordinate system by a system of $ ( n- 1) $ | ||
| + | equations of which exactly $ k $ | ||
| + | are linear. When $ k= n- 2 $, | ||
| + | the geodesic lines are planar, and are situated in two-dimensional Euclidean planes, and the space is said to be subprojective if all these two-dimensional Euclidean planes pass through a common point or are parallel in one direction (the common point is infinitely distant). | ||
| − | + | Let $ A _ {n} $ | |
| + | be an $ n $- | ||
| + | dimensional subprojective space with a torsion-free affine connection. With respect to a projective coordinate system $ x ^ {i} $ | ||
| + | of $ A _ {n} $, | ||
| + | the coefficients of the connection take the form | ||
| − | + | $$ | |
| + | \Gamma _ {jk} ^ {i} = x ^ {i} f _ {jk} + \delta _ {k} ^ {i} p _ {j} + \delta _ {j} ^ {i} p _ {k} ,\ \ | ||
| + | f _ {jk} = f _ {kj} , | ||
| + | $$ | ||
| − | + | where $ \delta _ {j} ^ {i} $ | |
| + | are the Kronecker symbols and | ||
| − | + | $$ | |
| + | p _ {k} = | ||
| + | \frac{1}{2} | ||
| + | ( \Gamma _ {kk} ^ {k} - f _ {kk} x ^ {k} ). | ||
| + | $$ | ||
| − | + | In this coordinate system, all two-dimensional Euclidean planes on which the geodesic lines of $ A _ {n} $ | |
| + | are situated pass through the coordinate origin. | ||
| − | + | In general, in a subprojective space $ A _ {n} $ | |
| + | there exists a canonical coordinate system $ x ^ {i} $ | ||
| + | in which the coefficients of the connection take the simplest form | ||
| − | + | $$ | |
| + | \Gamma _ {jk} ^ {i} = x ^ {i} f _ {jk} . | ||
| + | $$ | ||
| + | |||
| + | A Riemannian subprojective space $ V _ {n} $ | ||
| + | is defined in the same way; its metric reduces to one of three possible forms: | ||
| + | |||
| + | $$ | ||
| + | ds ^ {2} = g _ {\alpha \gamma } dx ^ \alpha dx ^ \gamma , | ||
| + | $$ | ||
where | where | ||
| − | 1) | + | 1) $ g _ {ik} = \partial _ {i} \tau \partial _ {k} \tau + ( \lambda / \theta ) \partial _ {ik} ( v/ \lambda ) $, |
| − | 2) | + | 2) $ g _ {ik} = \partial _ {i} \tau \partial _ {k} \tau + c( \lambda / \theta ) \partial _ {ik} \lambda $, |
| + | $ c = \textrm{ const } \neq 0 $; | ||
| + | here $ \theta $ | ||
| + | is an arbitrary function in the coordinates $ x ^ {i} $, | ||
| + | $ \theta $ | ||
| + | is a function of the variable $ \lambda / \theta $, | ||
| + | $ v $ | ||
| + | is a quadratic form in the $ x ^ {i} $, | ||
| + | $ \lambda $ | ||
| + | in 1) is a linear form and in 2) it is the square root of a quadratic form that is not a complete square. | ||
3) The exceptional case | 3) The exceptional case | ||
| − | + | $$ | |
| + | \theta ds ^ {2} = a _ {\alpha \beta } dx ^ \alpha dx ^ \beta + 2 \ | ||
| + | d \lambda dx ^ {n-} 1 + 2 dv dx ^ {n} , | ||
| + | $$ | ||
| + | |||
| + | where $ a _ {\alpha \beta } = \textrm{ const } $, | ||
| + | $ \mathop{\rm det} | a _ {\alpha \beta } | \neq 0 $, | ||
| + | $ \theta $ | ||
| + | is a homogeneous function of degree one in $ x ^ {n-} 1 $ | ||
| + | and $ x ^ {n} $, | ||
| + | and $ \lambda $ | ||
| + | and $ v $ | ||
| + | are functions related by | ||
| − | + | $$ | |
| − | + | \frac{1}{2} | |
| + | a _ {\alpha \beta } x ^ \alpha x ^ \beta + \lambda x ^ {n-} 1 + vx | ||
| + | ^ {n} = 0,\ \ | ||
| + | \alpha , \beta = 1 \dots n- 2 . | ||
| + | $$ | ||
| − | The functions | + | The functions $ \lambda $ |
| + | and $ v $ | ||
| + | are not homogeneous of the first degree. | ||
| − | All three cases can be reduced to a uniform expression by the choice of coordinates | + | All three cases can be reduced to a uniform expression by the choice of coordinates $ z ^ {i} $: |
| − | 1) | + | 1) $ ds ^ {2} = e ^ {- 2 \mu ( z ^ {1} ) } ( e _ {1} dz ^ {1 ^ {2} } + \dots + e _ {n} dz ^ {n ^ {2} } ) $, |
| − | 2) | + | 2) $ ds ^ {2} = e ^ {- 2 \mu ( z) } \sum _ {i=} 1 ^ {n} ( e _ {i} dz ^ {i ^ {2} } ) $, |
| + | $ z = ( \sum _ {i=} 1 ^ {n} e _ {i} dz ^ {i ^ {2} } ) ^ {1/2} $, | ||
| − | 3) | + | 3) $ ds ^ {2} = e ^ {- 2 \mu ( z ^ {1} ) } ( 2 dz ^ {1} dz ^ {2} + \sum _ {i=} 3 ^ {n} e _ {i} dz ^ {i ^ {2} } ) $, |
| + | $ i = 3 \dots n $ | ||
| + | $ ( e _ {i} = \textrm{ const } ) $. | ||
| + | All Riemannian subprojective spaces $ V _ {n} $ | ||
| + | are conformal Euclidean spaces (cf. [[Conformal Euclidean space|Conformal Euclidean space]]). Riemannian subprojective spaces belong to the class of semi-reducible Riemannian spaces and their metrics have a special structure. | ||
| − | Tensor criteria for conformal Euclidean subprojective spaces exist, distinguishing them from the class of all conformal Euclidean spaces. Every subprojective space | + | Tensor criteria for conformal Euclidean subprojective spaces exist, distinguishing them from the class of all conformal Euclidean spaces. Every subprojective space $ V _ {n} $( |
| + | apart from the case 3)) can be realized as a hypersurface in a Euclidean space $ E _ {n+} 1 $ | ||
| + | in the case 1), or as a hypersurface of rotation in $ E _ {n+} 1 $ | ||
| + | in the case 2). The converse is also true: Every hypersurface of rotation around a non-isotropic axis in a Euclidean space $ E _ {n+} 1 $, | ||
| + | $ n > 2 $, | ||
| + | is a Riemannian subprojective space with a metric of the form 2). | ||
| − | Motions in Riemannian subprojective spaces are defined in the usual way. The subprojective spaces | + | Motions in Riemannian subprojective spaces are defined in the usual way. The subprojective spaces $ V _ {n} $ |
| + | are characterized by the fact that if $ V _ {n} $ | ||
| + | is not a space of constant curvature, then it permits a maximal intransitive group of motions of order $ n( n- 1)/2 $, | ||
| + | and, conversely, every Riemannian space $ V _ {n} $ | ||
| + | that permits a maximal intransitive group of order $ n( n- 1)/2 $ | ||
| + | is a subprojective space. Riemannian subprojective spaces $ V _ {n} $ | ||
| + | are maximally-mobile non-Einsteinian spaces (spaces of constant curvature occupy the same position among the Einstein spaces). | ||
| − | The concept of a subprojective space permits the following generalizations: A space | + | The concept of a subprojective space permits the following generalizations: A space $ A _ {n} $ |
| + | with an affine connection is called a generalized subprojective space if its geodesic lines lie in Euclidean planes $ E _ {r+} 1 $, | ||
| + | $ 1 \leq r \leq n- 2 $, | ||
| + | that pass through a fixed plane $ E _ {r-} 1 $( | ||
| + | at a finite or infinite distance). | ||
====References==== | ====References==== | ||
<table><TR><TD valign="top">[1]</TD> <TD valign="top"> V.F. Kagan, "Subprojective spaces" , Moscow (1961) (In Russian)</TD></TR></table> | <table><TR><TD valign="top">[1]</TD> <TD valign="top"> V.F. Kagan, "Subprojective spaces" , Moscow (1961) (In Russian)</TD></TR></table> | ||
| − | |||
| − | |||
====Comments==== | ====Comments==== | ||
| − | |||
====References==== | ====References==== | ||
<table><TR><TD valign="top">[a1]</TD> <TD valign="top"> J.A. Schouten, "Ricci-calculus. An introduction to tensor analysis and its geometrical applications" , Springer (1954) (Translated from German)</TD></TR></table> | <table><TR><TD valign="top">[a1]</TD> <TD valign="top"> J.A. Schouten, "Ricci-calculus. An introduction to tensor analysis and its geometrical applications" , Springer (1954) (Translated from German)</TD></TR></table> | ||
Revision as of 08:24, 6 June 2020
One of the generalizations of spaces of constant curvature (of projective space). One defines a $ k $-
fold projective space with an affine connection and expresses its geodesic lines in some coordinate system by a system of $ ( n- 1) $
equations of which exactly $ k $
are linear. When $ k= n- 2 $,
the geodesic lines are planar, and are situated in two-dimensional Euclidean planes, and the space is said to be subprojective if all these two-dimensional Euclidean planes pass through a common point or are parallel in one direction (the common point is infinitely distant).
Let $ A _ {n} $ be an $ n $- dimensional subprojective space with a torsion-free affine connection. With respect to a projective coordinate system $ x ^ {i} $ of $ A _ {n} $, the coefficients of the connection take the form
$$ \Gamma _ {jk} ^ {i} = x ^ {i} f _ {jk} + \delta _ {k} ^ {i} p _ {j} + \delta _ {j} ^ {i} p _ {k} ,\ \ f _ {jk} = f _ {kj} , $$
where $ \delta _ {j} ^ {i} $ are the Kronecker symbols and
$$ p _ {k} = \frac{1}{2} ( \Gamma _ {kk} ^ {k} - f _ {kk} x ^ {k} ). $$
In this coordinate system, all two-dimensional Euclidean planes on which the geodesic lines of $ A _ {n} $ are situated pass through the coordinate origin.
In general, in a subprojective space $ A _ {n} $ there exists a canonical coordinate system $ x ^ {i} $ in which the coefficients of the connection take the simplest form
$$ \Gamma _ {jk} ^ {i} = x ^ {i} f _ {jk} . $$
A Riemannian subprojective space $ V _ {n} $ is defined in the same way; its metric reduces to one of three possible forms:
$$ ds ^ {2} = g _ {\alpha \gamma } dx ^ \alpha dx ^ \gamma , $$
where
1) $ g _ {ik} = \partial _ {i} \tau \partial _ {k} \tau + ( \lambda / \theta ) \partial _ {ik} ( v/ \lambda ) $,
2) $ g _ {ik} = \partial _ {i} \tau \partial _ {k} \tau + c( \lambda / \theta ) \partial _ {ik} \lambda $, $ c = \textrm{ const } \neq 0 $; here $ \theta $ is an arbitrary function in the coordinates $ x ^ {i} $, $ \theta $ is a function of the variable $ \lambda / \theta $, $ v $ is a quadratic form in the $ x ^ {i} $, $ \lambda $ in 1) is a linear form and in 2) it is the square root of a quadratic form that is not a complete square.
3) The exceptional case
$$ \theta ds ^ {2} = a _ {\alpha \beta } dx ^ \alpha dx ^ \beta + 2 \ d \lambda dx ^ {n-} 1 + 2 dv dx ^ {n} , $$
where $ a _ {\alpha \beta } = \textrm{ const } $, $ \mathop{\rm det} | a _ {\alpha \beta } | \neq 0 $, $ \theta $ is a homogeneous function of degree one in $ x ^ {n-} 1 $ and $ x ^ {n} $, and $ \lambda $ and $ v $ are functions related by
$$ \frac{1}{2} a _ {\alpha \beta } x ^ \alpha x ^ \beta + \lambda x ^ {n-} 1 + vx ^ {n} = 0,\ \ \alpha , \beta = 1 \dots n- 2 . $$
The functions $ \lambda $ and $ v $ are not homogeneous of the first degree.
All three cases can be reduced to a uniform expression by the choice of coordinates $ z ^ {i} $:
1) $ ds ^ {2} = e ^ {- 2 \mu ( z ^ {1} ) } ( e _ {1} dz ^ {1 ^ {2} } + \dots + e _ {n} dz ^ {n ^ {2} } ) $,
2) $ ds ^ {2} = e ^ {- 2 \mu ( z) } \sum _ {i=} 1 ^ {n} ( e _ {i} dz ^ {i ^ {2} } ) $, $ z = ( \sum _ {i=} 1 ^ {n} e _ {i} dz ^ {i ^ {2} } ) ^ {1/2} $,
3) $ ds ^ {2} = e ^ {- 2 \mu ( z ^ {1} ) } ( 2 dz ^ {1} dz ^ {2} + \sum _ {i=} 3 ^ {n} e _ {i} dz ^ {i ^ {2} } ) $, $ i = 3 \dots n $ $ ( e _ {i} = \textrm{ const } ) $. All Riemannian subprojective spaces $ V _ {n} $ are conformal Euclidean spaces (cf. Conformal Euclidean space). Riemannian subprojective spaces belong to the class of semi-reducible Riemannian spaces and their metrics have a special structure.
Tensor criteria for conformal Euclidean subprojective spaces exist, distinguishing them from the class of all conformal Euclidean spaces. Every subprojective space $ V _ {n} $( apart from the case 3)) can be realized as a hypersurface in a Euclidean space $ E _ {n+} 1 $ in the case 1), or as a hypersurface of rotation in $ E _ {n+} 1 $ in the case 2). The converse is also true: Every hypersurface of rotation around a non-isotropic axis in a Euclidean space $ E _ {n+} 1 $, $ n > 2 $, is a Riemannian subprojective space with a metric of the form 2).
Motions in Riemannian subprojective spaces are defined in the usual way. The subprojective spaces $ V _ {n} $ are characterized by the fact that if $ V _ {n} $ is not a space of constant curvature, then it permits a maximal intransitive group of motions of order $ n( n- 1)/2 $, and, conversely, every Riemannian space $ V _ {n} $ that permits a maximal intransitive group of order $ n( n- 1)/2 $ is a subprojective space. Riemannian subprojective spaces $ V _ {n} $ are maximally-mobile non-Einsteinian spaces (spaces of constant curvature occupy the same position among the Einstein spaces).
The concept of a subprojective space permits the following generalizations: A space $ A _ {n} $ with an affine connection is called a generalized subprojective space if its geodesic lines lie in Euclidean planes $ E _ {r+} 1 $, $ 1 \leq r \leq n- 2 $, that pass through a fixed plane $ E _ {r-} 1 $( at a finite or infinite distance).
References
| [1] | V.F. Kagan, "Subprojective spaces" , Moscow (1961) (In Russian) |
Comments
References
| [a1] | J.A. Schouten, "Ricci-calculus. An introduction to tensor analysis and its geometrical applications" , Springer (1954) (Translated from German) |
Subprojective space. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Subprojective_space&oldid=15475