Difference between revisions of "Natural operator in differential geometry"
From Encyclopedia of Mathematics
(Importing text file) |
m (AUTOMATIC EDIT (latexlist): Replaced 30 formulas out of 30 by TEX code with an average confidence of 2.0 and a minimal confidence of 2.0.) |
||
| Line 1: | Line 1: | ||
| − | + | <!--This article has been texified automatically. Since there was no Nroff source code for this article, | |
| + | the semi-automatic procedure described at https://encyclopediaofmath.org/wiki/User:Maximilian_Janisch/latexlist | ||
| + | was used. | ||
| + | If the TeX and formula formatting is correct, please remove this message and the {{TEX|semi-auto}} category. | ||
| − | + | Out of 30 formulas, 30 were replaced by TEX code.--> | |
| − | + | {{TEX|semi-auto}}{{TEX|done}} | |
| + | In the simplest case, one considers two natural bundles over $m$-dimensional manifolds $F$ and $G$, cf. [[Natural transformation in differential geometry|Natural transformation in differential geometry]]. A natural operator $A : F \rightarrow G$ is a system of operators $A _ {M}$ transforming every section $s$ of $F M$ into a section $A _ { M } ( s )$ of $G M$ for every $m$-dimensional [[Manifold|manifold]] $M$ with the following properties: | ||
| − | + | 1) $A$ commutes with the action of diffeomorphisms, i.e. | |
| − | + | \begin{equation*} A _ { N } ( F f \circ s \circ f ^ { - 1 } ) = ( G f ) \circ A _ { M } ( s ) \circ f ^ { - 1 } \end{equation*} | |
| − | + | for every [[Diffeomorphism|diffeomorphism]] $f : M \rightarrow N$; | |
| + | |||
| + | 2) $A$ has the localization property, i.e. $A _ { U } ( s | _ { U } ) = A _ { M } ( s ) | _ { U }$ for every open subset $U \subset M$; | ||
| + | |||
| + | 3) $A$ is regular, i.e. every smoothly parametrized family of sections is transformed into a smoothly parametrized family. | ||
This idea has been generalized to other categories over manifolds and to operators defined on certain distinguished classes of sections in [[#References|[a2]]]. | This idea has been generalized to other categories over manifolds and to operators defined on certain distinguished classes of sections in [[#References|[a2]]]. | ||
| − | The | + | The $k$th order natural operators $F \rightarrow G$ are in bijection with the natural transformations of the $k$th [[Jet|jet]] prolongation $J ^ { k } F$ into $G$. In this case the methods from [[#References|[a2]]] can be applied for finding natural operators. So it is important to have some criteria guaranteeing that all natural operators of a prescribed type have finite order. Fundamental results in this direction were deduced by J. Slovák, who developed a far-reaching generalization of the Peetre theorem to non-linear problems, [[#References|[a2]]]. However, in certain situations there exist natural operators of infinite order. |
| − | The first result about natural operators was deduced by R. Palais, [[#References|[a3]]], who proved that all linear natural operators transforming exterior | + | The first result about natural operators was deduced by R. Palais, [[#References|[a3]]], who proved that all linear natural operators transforming exterior $p$-forms into exterior $( p + 1 )$-forms are constant multiples of the exterior differential (cf. also [[Exterior form|Exterior form]]). In [[#References|[a2]]] new methods are used to prove that for $p \geq 1$ linearity even follows from naturality. |
Many concrete problems on finding all natural operators are solved in [[#References|[a2]]]. | Many concrete problems on finding all natural operators are solved in [[#References|[a2]]]. | ||
| − | The following result on the natural operators on morphisms of fibred manifolds is closely related to the geometry of the calculus of variations. On a fibred manifold with | + | The following result on the natural operators on morphisms of fibred manifolds is closely related to the geometry of the calculus of variations. On a fibred manifold with $m$-dimensional base, $m \geq 2$, there is no natural operator transforming $r$th order Lagrangeans into Poincaré–Cartan morphisms for $r \geq 3$, see [[#References|[a1]]]. In this case, one has to use an additional structure to distinguish a single Poincaré-Cartan form determined by a Lagrangean. |
====References==== | ====References==== | ||
| − | <table>< | + | <table><tr><td valign="top">[a1]</td> <td valign="top"> I. Kolář, "Natural operators related with the variational calculus" , ''Proc. Conf. Diff. Geom. Appl., Silesian Univ. Opava'' (1993) pp. 461–472</td></tr><tr><td valign="top">[a2]</td> <td valign="top"> I. Kolář, P.W. Michor, J. Slovák, "Natural operations in differential geometry" , Springer (1993)</td></tr><tr><td valign="top">[a3]</td> <td valign="top"> R. Palais, "Natural operations on differential forms" ''Trans. Amer. Math. Soc.'' , '''92''' (1959) pp. 125–141</td></tr></table> |
Latest revision as of 15:30, 1 July 2020
In the simplest case, one considers two natural bundles over $m$-dimensional manifolds $F$ and $G$, cf. Natural transformation in differential geometry. A natural operator $A : F \rightarrow G$ is a system of operators $A _ {M}$ transforming every section $s$ of $F M$ into a section $A _ { M } ( s )$ of $G M$ for every $m$-dimensional manifold $M$ with the following properties:
1) $A$ commutes with the action of diffeomorphisms, i.e.
\begin{equation*} A _ { N } ( F f \circ s \circ f ^ { - 1 } ) = ( G f ) \circ A _ { M } ( s ) \circ f ^ { - 1 } \end{equation*}
for every diffeomorphism $f : M \rightarrow N$;
2) $A$ has the localization property, i.e. $A _ { U } ( s | _ { U } ) = A _ { M } ( s ) | _ { U }$ for every open subset $U \subset M$;
3) $A$ is regular, i.e. every smoothly parametrized family of sections is transformed into a smoothly parametrized family.
This idea has been generalized to other categories over manifolds and to operators defined on certain distinguished classes of sections in [a2].
The $k$th order natural operators $F \rightarrow G$ are in bijection with the natural transformations of the $k$th jet prolongation $J ^ { k } F$ into $G$. In this case the methods from [a2] can be applied for finding natural operators. So it is important to have some criteria guaranteeing that all natural operators of a prescribed type have finite order. Fundamental results in this direction were deduced by J. Slovák, who developed a far-reaching generalization of the Peetre theorem to non-linear problems, [a2]. However, in certain situations there exist natural operators of infinite order.
The first result about natural operators was deduced by R. Palais, [a3], who proved that all linear natural operators transforming exterior $p$-forms into exterior $( p + 1 )$-forms are constant multiples of the exterior differential (cf. also Exterior form). In [a2] new methods are used to prove that for $p \geq 1$ linearity even follows from naturality.
Many concrete problems on finding all natural operators are solved in [a2].
The following result on the natural operators on morphisms of fibred manifolds is closely related to the geometry of the calculus of variations. On a fibred manifold with $m$-dimensional base, $m \geq 2$, there is no natural operator transforming $r$th order Lagrangeans into Poincaré–Cartan morphisms for $r \geq 3$, see [a1]. In this case, one has to use an additional structure to distinguish a single Poincaré-Cartan form determined by a Lagrangean.
References
| [a1] | I. Kolář, "Natural operators related with the variational calculus" , Proc. Conf. Diff. Geom. Appl., Silesian Univ. Opava (1993) pp. 461–472 |
| [a2] | I. Kolář, P.W. Michor, J. Slovák, "Natural operations in differential geometry" , Springer (1993) |
| [a3] | R. Palais, "Natural operations on differential forms" Trans. Amer. Math. Soc. , 92 (1959) pp. 125–141 |
How to Cite This Entry:
Natural operator in differential geometry. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Natural_operator_in_differential_geometry&oldid=13188
Natural operator in differential geometry. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Natural_operator_in_differential_geometry&oldid=13188
This article was adapted from an original article by Ivan Kolář (originator), which appeared in Encyclopedia of Mathematics - ISBN 1402006098. See original article