Talk:Cut locus

I have added a special case definition, along with its reference. Moreover, I made some editing changes. Should the "STUB" be removed now?

How do you find the example? Is it a good one? Drorata (talk) 17:08, 29 October 2008 (UTC)Reply

This article seems to take "metric space" to mean a topological space for which lengths of curves are defined. However, the standard definition is simply a set with a distance function -- i.e., a general metric space does not have enough structure to define the length of curves. Maybe it's best to merge this article with the one on the cut locus for a Riemannian manifold. — Preceding unsigned comment added by 66.57.43.129 (talk) 00:18, 29 April 2010 (UTC)Reply

    Y Merger complete. Klbrain (talk) 11:34, 23 June 2024 (UTC)Reply

@Klbrain both articles are about the exact same subject, so the merger needs to merge them to top level, not just insert one as a section of the other. –jacobolus (t) 16:44, 23 June 2024 (UTC)Reply

Feel free to fix in situ. No objection from me! Klbrain (talk) 18:50, 23 June 2024 (UTC)Reply

A very brief literature search turns up http://www.numdam.org/item/CM_1978__37_1_103_0.pdf which says:

Historically, the cut locus was first introduced by Poincare [10] for compact simply connected surfaces of positive curvature. In 1935, Summer B. Meyers [7], [8], and J.H.C. Whitehead [15] both studied the cut locus. Whitehead showed that any compact n-dimensional Riemannian manifold decomposes into the cut locus and an open cell with the cut locus as the cell boundary. Meyers showed that forcompact analytic surfaces the cut locus is a graph, for simply connected surfaces the graph is a tree, the end points of which are conjugate to the origin of the cut locus and are cusps of the locus of first conjugate points.

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[7] S.B. MYERS: Connections between differential geometry and topology: I. Simply connected surfaces. Duke Math. J., 1 (1935) 376-391.

[8] S.B. MYERS: Connections between differential geometry and topology: II. Closed surfaces. Duke Math. J., 2 (1936) 95-102.

[10] H. POINCARÉ: Trans. Amer. Math. Soc., 6 (1905) 243.

[15] J.H.C. WHITEHEAD: On the covering of a complete space by the geodesics through a point. Ann. of Math., 36 (1935) 679-704.

This paper also has a definition:

If ⁠${\displaystyle \alpha }$ ⁠ is a metric on ⁠${\displaystyle M}$ ⁠ then ⁠${\displaystyle C(p,\alpha )}$ ⁠ will denote the cut locus in ⁠${\displaystyle M}$ ⁠ with respect to ⁠${\displaystyle p}$ ⁠ and the metric ⁠${\displaystyle \alpha }$ ⁠ i.e. the set of those points ⁠${\displaystyle q}$ ⁠ in ⁠${\displaystyle M}$ ⁠ which are joined to ⁠${\displaystyle p}$ ⁠ by a length minimizing geodesic which fails to minimize the length to points beyond ⁠${\displaystyle q}$ ⁠ on the geodesic.

Another paper that turned up recommends the survey paper:

Shoshichi Kobayashi. On conjugate and cut loci. In S.-S. Chern, editor, Studies in global geometry and analysis, number 4 in Studies in Mathematics, pages 96–122. MAA, Englewood Cliffs, NJ, 1967.

–jacobolus (t) 17:43, 23 June 2024 (UTC)Reply