Difference between revisions of "Distribution of tangent subspaces"
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− | ''Distribution'' on a smooth manifold is a collection of subspaces $L_a\subseteq T_aM$ of the tangent spaces $T_a M$, which depends in a regular way (smooth, analytic etc.) on the ''base point'' $a\in M$. In particular, the dimension of all subspaces should be constant (the ''dimension | + | {{TEX|done}} |
+ | ''Distribution'' on a smooth manifold is a collection of subspaces $L_a\subseteq T_aM$ of the tangent spaces $T_a M$, which depends in a regular way (smooth, analytic etc.) on the ''base point'' $a\in M$. In particular, the dimension of all subspaces should be constant (the ''dimension'', sometimes the ''rank'' of the distribution). If the regularity fails on a small subset $\varSigma\subset M$, one sometimes says about ''singular distribution'' with the ''singular locus'' $\varSigma$. | ||
One-dimensional distributions with $\dim L_a=1$ are sometimes called the ''line fields''. | One-dimensional distributions with $\dim L_a=1$ are sometimes called the ''line fields''. | ||
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If $v_1,\dots,v_k$ are vector fields on $M$, their span is a distribution provided that the rank of the tuple of fields is constant over all points of $m$. A single vector field $v$ defines a line field (distribution of rank 1) over the set of points $M\smallsetminus\varSigma$ of its nonzero values, where $\varSigma=\{a\in M:\ v(a)=0\}$. | If $v_1,\dots,v_k$ are vector fields on $M$, their span is a distribution provided that the rank of the tuple of fields is constant over all points of $m$. A single vector field $v$ defines a line field (distribution of rank 1) over the set of points $M\smallsetminus\varSigma$ of its nonzero values, where $\varSigma=\{a\in M:\ v(a)=0\}$. | ||
− | If $\xi_1,\dots,\xi_l\in\Lambda^1(M)$ are differential 1-forms on $M$, then their common null spaces $\ | + | If $\xi_1,\dots,\xi_l\in\Lambda^1(M)$ are differential 1-forms on $M$, then their common null spaces $\bigcap_i\operatorname{Ker}\xi_i$ is a distribution provided that the rank of the tuple of forms is constant over all points of $M$. |
=== Integrability of distributions === | === Integrability of distributions === | ||
− | + | A distribution $L=\{L_x\}$ of rank $k$, $0<k<n$, is called | |
− | $0<k<n$, is called integrable in a domain $U\subseteq M$, if | + | integrable in a domain $U\subseteq M$, if through each point |
− | through each point $a\in M$ passes the germ of a | + | $a\in M$ passes the germ of a $k$-dimensional submanifold |
− | $k$-dimensional submanifold $N_a=N$ which is tangent to the | + | $N_a=N$ which is tangent to the distribution: $\forall x\in N\ |
− | distribution: $\forall x\in N\ L_x=T_xN\subset T_xM$. | + | L_x=T_xN\subset T_xM$. |
'''Example'''. Each vector field defines an integrable | '''Example'''. Each vector field defines an integrable | ||
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commutators belong to the span: | commutators belong to the span: | ||
$$ | $$ | ||
− | \forall i,j\ | + | \forall i,j=1,\dots,k\qquad [v_i,v_j]=\sum_{s=1}^k |
+ | \varphi_{ijs} v_s | ||
$$ | $$ | ||
− | with suitable functions $\varphi_{ijs}$. | + | with suitable smooth functions $\varphi_{ijs}$. |
A distribution spanned by a tuple of $1$-forms | A distribution spanned by a tuple of $1$-forms | ||
$\xi_1,\dots,\xi_k$ is integrable if and only if | $\xi_1,\dots,\xi_k$ is integrable if and only if | ||
$$ | $$ | ||
− | \rd \xi_i=\sum_{s=1}^k\ | + | \rd \xi_i=\sum_{s=1}^k\eta_{is}\land\xi_s |
$$ | $$ | ||
− | with suitable 1-forms $\ | + | with suitable 1-forms $\eta_{is}$. |
+ | |||
+ | ====Comments==== | ||
+ | * The conditions appearing in the Frobenius theorem, are often referred to as ''involutivity'' of the distribution. | ||
+ | * The involutivity is automatic for 1-dimensional distributions: this is reflected in absence of extra integrability conditions in the theorem of existence of solutions of ordinary differential equations. | ||
+ | * An involutive system of vector fields can always be locally generated by ''commuting'' vector fields $w_1,\dots,w_k$ with $[w_i,w_j]=0$ for all $i,j$. | ||
+ | * Algebraically, a distribution cannot be seen as a finitely generated $C^\infty(M)$-submodule of sections of the tangent bundle $TM$ (generated by the fields $v_1,\dots,v_k$). The involutivity means that this submodule is closed by the commutator action. | ||
+ | * Algebraically, a distribution can be seen as an ideal (generated by the forms $\xi_1,\dots,\xi_k)$ in the graded [[exterior algebra]] $\Lambda^\bullet(M)=\Lambda^0(M)\oplus\Lambda^1(M)\oplus\cdots\oplus\Lambda^n(M)$. The involutivity means that this ideal is closed by the [[exterior differential]] $\rd:\Lambda^i(M)\to\Lambda^{i+1}(M)$. | ||
+ | |||
+ | === References === | ||
+ | {| | ||
+ | |- | ||
+ | |valign="top"|{{Ref|B}}||valign="top"|Boothby, W. M. ''An introduction to differentiable manifolds and Riemannian geometry'', Pure and Applied Mathematics, '''120'''. Academic Press, Inc., Orlando, FL, 1986, {{MR|0861409}} | ||
+ | |- | ||
+ | |valign="top"|{{Ref|W}}||valign="top"|Warner, F. W. ''Foundations of differentiable manifolds and Lie groups''. Graduate Texts in Mathematics, '''94'''. Springer-Verlag, New York-Berlin, 1983. {{MR|0722297}} | ||
+ | |- | ||
+ | |valign="top"|{{Ref|M}}||valign="top"|Morita, S. ''Geometry of differential forms'', Translations of Mathematical Monographs, '''201'''. Iwanami Series in Modern Mathematics. American Mathematical Society, Providence, RI, 2001. {{MR|1851352}} | ||
+ | |- | ||
+ | |} |
Latest revision as of 15:17, 1 May 2014
Distribution on a smooth manifold is a collection of subspaces $L_a\subseteq T_aM$ of the tangent spaces $T_a M$, which depends in a regular way (smooth, analytic etc.) on the base point $a\in M$. In particular, the dimension of all subspaces should be constant (the dimension, sometimes the rank of the distribution). If the regularity fails on a small subset $\varSigma\subset M$, one sometimes says about singular distribution with the singular locus $\varSigma$.
One-dimensional distributions with $\dim L_a=1$ are sometimes called the line fields.
Definitions
In formal terms, a distribution is a subset of the tangent bundle $TM$, which itself has the inherited structure of the vector bundle over $M$. Usually the cases of $0$-dimensional and $n$-dimensional subspaces are excluded from consideration.
If $v_1,\dots,v_k$ are vector fields on $M$, their span is a distribution provided that the rank of the tuple of fields is constant over all points of $m$. A single vector field $v$ defines a line field (distribution of rank 1) over the set of points $M\smallsetminus\varSigma$ of its nonzero values, where $\varSigma=\{a\in M:\ v(a)=0\}$.
If $\xi_1,\dots,\xi_l\in\Lambda^1(M)$ are differential 1-forms on $M$, then their common null spaces $\bigcap_i\operatorname{Ker}\xi_i$ is a distribution provided that the rank of the tuple of forms is constant over all points of $M$.
Integrability of distributions
A distribution $L=\{L_x\}$ of rank $k$, $0<k<n$, is called integrable in a domain $U\subseteq M$, if through each point $a\in M$ passes the germ of a $k$-dimensional submanifold $N_a=N$ which is tangent to the distribution: $\forall x\in N\ L_x=T_xN\subset T_xM$.
Example. Each vector field defines an integrable distribution outside of its zero locus: the 1-dimensional submanifold (curve) through a point $a$ is the integral curve of $v$ with the initial condition at this point.
Frobenius integrability theorem. A distribution spanned by a tuple of vector fields $v_1,\dots,v_k$ over the set where their rank is $k$, is integrable if and only if their commutators belong to the span: $$ \forall i,j=1,\dots,k\qquad [v_i,v_j]=\sum_{s=1}^k \varphi_{ijs} v_s $$ with suitable smooth functions $\varphi_{ijs}$.
A distribution spanned by a tuple of $1$-forms $\xi_1,\dots,\xi_k$ is integrable if and only if $$ \rd \xi_i=\sum_{s=1}^k\eta_{is}\land\xi_s $$ with suitable 1-forms $\eta_{is}$.
Comments
- The conditions appearing in the Frobenius theorem, are often referred to as involutivity of the distribution.
- The involutivity is automatic for 1-dimensional distributions: this is reflected in absence of extra integrability conditions in the theorem of existence of solutions of ordinary differential equations.
- An involutive system of vector fields can always be locally generated by commuting vector fields $w_1,\dots,w_k$ with $[w_i,w_j]=0$ for all $i,j$.
- Algebraically, a distribution cannot be seen as a finitely generated $C^\infty(M)$-submodule of sections of the tangent bundle $TM$ (generated by the fields $v_1,\dots,v_k$). The involutivity means that this submodule is closed by the commutator action.
- Algebraically, a distribution can be seen as an ideal (generated by the forms $\xi_1,\dots,\xi_k)$ in the graded exterior algebra $\Lambda^\bullet(M)=\Lambda^0(M)\oplus\Lambda^1(M)\oplus\cdots\oplus\Lambda^n(M)$. The involutivity means that this ideal is closed by the exterior differential $\rd:\Lambda^i(M)\to\Lambda^{i+1}(M)$.
References
[B] | Boothby, W. M. An introduction to differentiable manifolds and Riemannian geometry, Pure and Applied Mathematics, 120. Academic Press, Inc., Orlando, FL, 1986, MR0861409 |
[W] | Warner, F. W. Foundations of differentiable manifolds and Lie groups. Graduate Texts in Mathematics, 94. Springer-Verlag, New York-Berlin, 1983. MR0722297 |
[M] | Morita, S. Geometry of differential forms, Translations of Mathematical Monographs, 201. Iwanami Series in Modern Mathematics. American Mathematical Society, Providence, RI, 2001. MR1851352 |
Distribution of tangent subspaces. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Distribution_of_tangent_subspaces&oldid=25883