Difference between revisions of "Spray"
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| − | ''on a differentiable manifold | + | {{TEX|done}} |
| + | ''on a differentiable manifold $M$'' | ||
| − | A vector field | + | A vector field $W$ on the tangent space $TM$ which, in terms of the local coordinates $(x^1,\dots,x^n,v^1,\dots,v^n)$ on $TM$ associated in a natural way with the local coordinates $(x^1,\dots,x^n)$ on $M$, has components $(v^1,\dots,v^n,f^1,\dots,f^n)$, where $f^i=f^i(x^1,\dots,x^n,v^1,\dots,v^n)$ are functions of class $C^1$ which are, for fixed $x^1,\dots,x^n$, positive homogeneous functions in $v^1,\dots,v^n$ of degree 2 (these properties of $W$ do not depend on the actual choice of the local coordinates). The system of differential equations determined by this vector field, |
| − | + | $$\frac{dx^i}{dt}=v^i,\quad\frac{dv^i}{dt}=f^i(x^1,\dots,x^n,v^1,\dots,v^n),\quad i=1,\dots,n,$$ | |
is equivalent to the system of second-order differential equations | is equivalent to the system of second-order differential equations | ||
| − | + | $$\frac{d^2x^i}{dt^2}=f^i\left(x^1,\dots,x^n,\frac{dx^1}{dt},\dots,\frac{dx^n}{dt}\right);$$ | |
| − | therefore a spray describes (and moreover in an invariant manner, that is, independent of the coordinate system) a system of such equations on | + | therefore a spray describes (and moreover in an invariant manner, that is, independent of the coordinate system) a system of such equations on $M$. |
| − | The most important case of a spray is when the | + | The most important case of a spray is when the $f^i$ are polynomials of the second degree in the $v^i$: |
| − | + | $$f^i=\sum\Gamma_{jk}^i(x^1,\dots,x^n)v^jv^k,\quad\Gamma_{jk}^i=\Gamma_{kj}^i.\label{*}\tag{*}$$ | |
| − | In this case the | + | In this case the $\Gamma_{jk}^i$ give an [[Affine connection|affine connection]] on $M$ with zero torsion tensor. Conversely, for every affine connection the equations of the geodesic lines are given by a certain spray with $f^i$ of the form \eqref{*} (where when going from the connection to the spray, the $\Gamma_{jk}^i$ symmetrize with respect to the suffixes). If the field $W$ is of class $C^2$, then $f^i$ must have the form \eqref{*}. In the general case, however, $W$ may be smooth outside the zero section of the bundle $TM$, but need not be a field of class $C^2$ near this section. In such a situation one sometimes talks about a generalized spray, leaving the term "spray" only for the special case \eqref{*}. The differential equations for geodesics in Finsler geometry give rise to a generalized spray. |
It is possible to give a definition of a spray in invariant terms, which is suitable also for Banach manifolds (see [[#References|[1]]]). | It is possible to give a definition of a spray in invariant terms, which is suitable also for Banach manifolds (see [[#References|[1]]]). | ||
Latest revision as of 15:19, 14 February 2020
on a differentiable manifold $M$
A vector field $W$ on the tangent space $TM$ which, in terms of the local coordinates $(x^1,\dots,x^n,v^1,\dots,v^n)$ on $TM$ associated in a natural way with the local coordinates $(x^1,\dots,x^n)$ on $M$, has components $(v^1,\dots,v^n,f^1,\dots,f^n)$, where $f^i=f^i(x^1,\dots,x^n,v^1,\dots,v^n)$ are functions of class $C^1$ which are, for fixed $x^1,\dots,x^n$, positive homogeneous functions in $v^1,\dots,v^n$ of degree 2 (these properties of $W$ do not depend on the actual choice of the local coordinates). The system of differential equations determined by this vector field,
$$\frac{dx^i}{dt}=v^i,\quad\frac{dv^i}{dt}=f^i(x^1,\dots,x^n,v^1,\dots,v^n),\quad i=1,\dots,n,$$
is equivalent to the system of second-order differential equations
$$\frac{d^2x^i}{dt^2}=f^i\left(x^1,\dots,x^n,\frac{dx^1}{dt},\dots,\frac{dx^n}{dt}\right);$$
therefore a spray describes (and moreover in an invariant manner, that is, independent of the coordinate system) a system of such equations on $M$.
The most important case of a spray is when the $f^i$ are polynomials of the second degree in the $v^i$:
$$f^i=\sum\Gamma_{jk}^i(x^1,\dots,x^n)v^jv^k,\quad\Gamma_{jk}^i=\Gamma_{kj}^i.\label{*}\tag{*}$$
In this case the $\Gamma_{jk}^i$ give an affine connection on $M$ with zero torsion tensor. Conversely, for every affine connection the equations of the geodesic lines are given by a certain spray with $f^i$ of the form \eqref{*} (where when going from the connection to the spray, the $\Gamma_{jk}^i$ symmetrize with respect to the suffixes). If the field $W$ is of class $C^2$, then $f^i$ must have the form \eqref{*}. In the general case, however, $W$ may be smooth outside the zero section of the bundle $TM$, but need not be a field of class $C^2$ near this section. In such a situation one sometimes talks about a generalized spray, leaving the term "spray" only for the special case \eqref{*}. The differential equations for geodesics in Finsler geometry give rise to a generalized spray.
It is possible to give a definition of a spray in invariant terms, which is suitable also for Banach manifolds (see [1]).
References
| [1] | S. Lang, "Introduction to differentiable manifolds" , Interscience (1967) |
Comments
The spray of an affine connection is also called the geodesic spray of this connection.
References
| [a1] | D. Gromoll, W. Klingenberg, W. Meyer, "Riemannsche Geometrie im Grossen" , Springer (1968) |
Spray. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Spray&oldid=13449