Difference between revisions of "Equi-distant"
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− | ''of a set | + | {{TEX|done}} |
+ | ''of a set $M$ in a metric space $R$'' | ||
− | The boundary of the [[Tubular neighbourhood|tubular neighbourhood]] of | + | The boundary of the [[Tubular neighbourhood|tubular neighbourhood]] of $M$ in $R$ consisting of the balls of the same radius $d$ with centres in $M$. If $M$ is a differentiable submanifold $M^k$ in a Riemannian space $V^n$, then the equi-distant of $M$ is given (in a more restricted sense) by the set of end-points of the segments of equal length measured from $M^k$ on the geodesics perpendicular to $M^k$ at the corresponding points. If $V^n$ is complete, then the equi-distant is the image under the [[Exponential mapping|exponential mapping]] of the vectors of constant length $d$ in the normal bundle of $M^k$ in $V^n$. If $V^n$ is not complete, then the equi-distant exists only for sufficiently small values of $d$. |
Examples of equi-distants. 1) An equi-distant in the Lobachevskii plane (a hypercycle) is the orthogonal trajectory of the pencil of straight lines perpendicular to some straight line (to a basic line, or basis). The equi-distant consists of two branches situated on different sides from the basis line and concave towards the basis. The curvature of the equi-distant is constant. 2) An equi-distant in the Lobachevskii space is a surface of constant positive exterior curvature. | Examples of equi-distants. 1) An equi-distant in the Lobachevskii plane (a hypercycle) is the orthogonal trajectory of the pencil of straight lines perpendicular to some straight line (to a basic line, or basis). The equi-distant consists of two branches situated on different sides from the basis line and concave towards the basis. The curvature of the equi-distant is constant. 2) An equi-distant in the Lobachevskii space is a surface of constant positive exterior curvature. |
Latest revision as of 21:08, 14 April 2014
of a set $M$ in a metric space $R$
The boundary of the tubular neighbourhood of $M$ in $R$ consisting of the balls of the same radius $d$ with centres in $M$. If $M$ is a differentiable submanifold $M^k$ in a Riemannian space $V^n$, then the equi-distant of $M$ is given (in a more restricted sense) by the set of end-points of the segments of equal length measured from $M^k$ on the geodesics perpendicular to $M^k$ at the corresponding points. If $V^n$ is complete, then the equi-distant is the image under the exponential mapping of the vectors of constant length $d$ in the normal bundle of $M^k$ in $V^n$. If $V^n$ is not complete, then the equi-distant exists only for sufficiently small values of $d$.
Examples of equi-distants. 1) An equi-distant in the Lobachevskii plane (a hypercycle) is the orthogonal trajectory of the pencil of straight lines perpendicular to some straight line (to a basic line, or basis). The equi-distant consists of two branches situated on different sides from the basis line and concave towards the basis. The curvature of the equi-distant is constant. 2) An equi-distant in the Lobachevskii space is a surface of constant positive exterior curvature.
Equi-distant. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Equi-distant&oldid=13552