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Ptolemy's inequality

April 10, 2024

In Euclidean geometry, Ptolemy's inequality relates the six distances determined by four points in the plane or in a higher-dimensional space. It states that, for any four points A, B, C, and D, the following inequality holds:

Four points and their six distances. The points are not co-circular, so Ptolemy's inequality is strict for these points.

It is named after the Greek astronomer and mathematician Ptolemy.

The four points can be ordered in any of three distinct ways (counting reversals as not distinct) to form three different quadrilaterals, for each of which the sum of the products of opposite sides is at least as large as the product of the diagonals. Thus, the three product terms in the inequality can be additively permuted to put any one of them on the right side of the inequality, so the three products of opposite sides or of diagonals of any one of the quadrilaterals must obey the triangle inequality.[1]

As a special case, Ptolemy's theorem states that the inequality becomes an equality when the four points lie in cyclic order on a circle. The other case of equality occurs when the four points are collinear in order. The inequality does not generalize from Euclidean spaces to arbitrary metric spaces. The spaces where it remains valid are called the Ptolemaic spaces; they include the inner product spaces, Hadamard spaces, and shortest path distances on Ptolemaic graphs.

Assumptions and derivation edit

Ptolemy's inequality is often stated for a special case, in which the four points are the vertices of a convex quadrilateral, given in cyclic order.[2][3] However, the theorem applies more generally to any four points; it is not required that the quadrilateral they form be convex, simple, or even planar.

For points in the plane, Ptolemy's inequality can be derived from the triangle inequality by an inversion centered at one of the four points.[4][5] Alternatively, it can be derived by interpreting the four points as complex numbers, using the complex number identity:

 

to construct a triangle whose side lengths are the products of sides of the given quadrilateral, and applying the triangle inequality to this triangle.[6] One can also view the points as belonging to the complex projective line, express the inequality in the form that the absolute values of two cross-ratios of the points sum to at least one, and deduce this from the fact that the cross-ratios themselves add to exactly one.[7]

A proof of the inequality for points in three-dimensional space can be reduced to the planar case, by observing that for any non-planar quadrilateral, it is possible to rotate one of the points around the diagonal until the quadrilateral becomes planar, increasing the other diagonal's length and keeping the other five distances constant.[6] In spaces of higher dimension than three, any four points lie in a three-dimensional subspace, and the same three-dimensional proof can be used.

Four concyclic points edit

Main article: Ptolemy's theorem

For four points in order around a circle, Ptolemy's inequality becomes an equality, known as Ptolemy's theorem:

 

In the inversion-based proof of Ptolemy's inequality, transforming four co-circular points by an inversion centered at one of them causes the other three to become collinear, so the triangle equality for these three points (from which Ptolemy's inequality may be derived) also becomes an equality.[5] For any other four points, Ptolemy's inequality is strict.

In three dimensions edit

Four non-coplanar points A, B, C, and D in 3D form a tetrahedron. In this case, the strict inequality holds:  .[8]

In general metric spaces edit

 
A cycle graph in which the distances disobey Ptolemy's inequality

Ptolemy's inequality holds more generally in any inner product space,[1][9] and whenever it is true for a real normed vector space, that space must be an inner product space.[9][10]

For other types of metric space, the inequality may or may not be valid. A space in which it holds is called Ptolemaic. For instance, consider the four-vertex cycle graph, shown in the figure, with all edge lengths equal to 1. The sum of the products of opposite sides is 2. However, diagonally opposite vertices are at distance 2 from each other, so the product of the diagonals is 4, bigger than the sum of products of sides. Therefore, the shortest path distances in this graph are not Ptolemaic. The graphs in which the distances obey Ptolemy's inequality are called the Ptolemaic graphs and have a restricted structure compared to arbitrary graphs; in particular, they disallow induced cycles of length greater than three, such as the one shown.[11]

The Ptolemaic spaces include all CAT(0) spaces and in particular all Hadamard spaces. If a complete Riemannian manifold is Ptolemaic, it is necessarily a Hadamard space.[12]

Inner product spaces edit

See also: Polarization identity

Suppose that   is a norm on a vector space   Then this norm satisfies Ptolemy's inequality:

 
if and only if there exists an inner product   on   such that   for all vectors  [13] Another necessary and sufficient condition for there to exist such an inner product is for the norm to satisfy the parallelogram law:
 
If this is the case then this inner product will be unique and it can be defined in terms of the norm by using the polarization identity.

See also edit

References edit

  1. ^ a b Schoenberg, I. J. (1940), "On metric arcs of vanishing Menger curvature", Annals of Mathematics, Second Series, 41 (4): 715–726, doi:10.2307/1968849, JSTOR 1968849, MR 0002903.
  2. ^ Steele, J. Michael (2004), "Exercise 4.6 (Ptolemy's Inequality)", The Cauchy-Schwarz Master Class: An Introduction to the Art of Mathematical Inequalities, MAA problem books, Cambridge University Press, p. 69, ISBN 9780521546775.
  3. ^ Alsina, Claudi; Nelsen, Roger B. (2009), "6.1 Ptolemy's inequality", When Less is More: Visualizing Basic Inequalities, Dolciani Mathematical Expositions, vol. 36, Mathematical Association of America, pp. 82–83, ISBN 9780883853429.
  4. ^ Apostol (1967) attributes the inversion-based proof to textbooks by R. A. Johnson (1929) and Howard Eves (1963).
  5. ^ a b Stankova, Zvezdelina; Rike, Tom, eds. (2008), "Problem 7 (Ptolemy's Inequality)", A Decade of the Berkeley Math Circle: The American Experience, MSRI Mathematical Circles Library, vol. 1, American Mathematical Society, p. 18, ISBN 9780821846834.
  6. ^ a b Apostol 1967.
  7. ^ Silvester, John R. (2001), "Proposition 9.10 (Ptolemy's theorem)", Geometry: Ancient and Modern, Oxford University Press, p. 229, ISBN 9780198508250.
  8. ^ Zhu, Hanlin (1984). "68.25 A Tetrahedron Inequality". The Mathematical Gazette. 68 (445): 200–202. doi:10.2307/3616345. ISSN 0025-5572.
  9. ^ a b Giles, J. R. (2000), "Exercise 12", Introduction to the Analysis of Normed Linear Spaces, Australian Mathematical Society lecture series, vol. 13, Cambridge University Press, p. 47, ISBN 9780521653756.
  10. ^ Schoenberg, I. J. (1952), "A remark on M. M. Day's characterization of inner-product spaces and a conjecture of L. M. Blumenthal", Proceedings of the American Mathematical Society, 3 (6): 961–964, doi:10.2307/2031742, JSTOR 2031742, MR 0052035.
  11. ^ Howorka, Edward (1981), "A characterization of Ptolemaic graphs", Journal of Graph Theory, 5 (3): 323–331, doi:10.1002/jgt.3190050314, MR 0625074.
  12. ^ Buckley, S. M.; Falk, K.; Wraith, D. J. (2009), "Ptolemaic spaces and CAT(0)", Glasgow Mathematical Journal, 51 (2): 301–314, doi:10.1017/S0017089509004984, MR 2500753.
  13. ^ Apostol, Tom M. (1967). "Ptolemy's Inequality and the Chordal Metric". Mathematics Magazine. 40 (5): 233–235. doi:10.2307/2688275. JSTOR 2688275. MR 0225213.

April 10, 2024
ptolemy, inequality, euclidean, geometry, relates, distances, determined, four, points, plane, higher, dimensional, space, states, that, four, points, following, inequality, holds, four, points, their, distances, points, circular, strict, these, points, displa. In Euclidean geometry Ptolemy s inequality relates the six distances determined by four points in the plane or in a higher dimensional space It states that for any four points A B C and D the following inequality holds Four points and their six distances The points are not co circular so Ptolemy s inequality is strict for these points AB CD BC DA AC BD displaystyle overline AB cdot overline CD overline BC cdot overline DA geq overline AC cdot overline BD It is named after the Greek astronomer and mathematician Ptolemy The four points can be ordered in any of three distinct ways counting reversals as not distinct to form three different quadrilaterals for each of which the sum of the products of opposite sides is at least as large as the product of the diagonals Thus the three product terms in the inequality can be additively permuted to put any one of them on the right side of the inequality so the three products of opposite sides or of diagonals of any one of the quadrilaterals must obey the triangle inequality 1 As a special case Ptolemy s theorem states that the inequality becomes an equality when the four points lie in cyclic order on a circle The other case of equality occurs when the four points are collinear in order The inequality does not generalize from Euclidean spaces to arbitrary metric spaces The spaces where it remains valid are called the Ptolemaic spaces they include the inner product spaces Hadamard spaces and shortest path distances on Ptolemaic graphs Contents 1 Assumptions and derivation 2 Four concyclic points 3 In three dimensions 4 In general metric spaces 5 Inner product spaces 6 See also 7 ReferencesAssumptions and derivation editPtolemy s inequality is often stated for a special case in which the four points are the vertices of a convex quadrilateral given in cyclic order 2 3 However the theorem applies more generally to any four points it is not required that the quadrilateral they form be convex simple or even planar For points in the plane Ptolemy s inequality can be derived from the triangle inequality by an inversion centered at one of the four points 4 5 Alternatively it can be derived by interpreting the four points as complex numbers using the complex number identity A B C D A D B C A C B D displaystyle A B C D A D B C A C B D nbsp to construct a triangle whose side lengths are the products of sides of the given quadrilateral and applying the triangle inequality to this triangle 6 One can also view the points as belonging to the complex projective line express the inequality in the form that the absolute values of two cross ratios of the points sum to at least one and deduce this from the fact that the cross ratios themselves add to exactly one 7 A proof of the inequality for points in three dimensional space can be reduced to the planar case by observing that for any non planar quadrilateral it is possible to rotate one of the points around the diagonal until the quadrilateral becomes planar increasing the other diagonal s length and keeping the other five distances constant 6 In spaces of higher dimension than three any four points lie in a three dimensional subspace and the same three dimensional proof can be used Four concyclic points editMain article Ptolemy s theorem For four points in order around a circle Ptolemy s inequality becomes an equality known as Ptolemy s theorem AB CD AD BC AC BD displaystyle overline AB cdot overline CD overline AD cdot overline BC overline AC cdot overline BD nbsp In the inversion based proof of Ptolemy s inequality transforming four co circular points by an inversion centered at one of them causes the other three to become collinear so the triangle equality for these three points from which Ptolemy s inequality may be derived also becomes an equality 5 For any other four points Ptolemy s inequality is strict In three dimensions editFour non coplanar points A B C and D in 3D form a tetrahedron In this case the strict inequality holds AB CD BC DA gt AC BD displaystyle overline AB cdot overline CD overline BC cdot overline DA gt overline AC cdot overline BD nbsp 8 In general metric spaces edit nbsp A cycle graph in which the distances disobey Ptolemy s inequalityPtolemy s inequality holds more generally in any inner product space 1 9 and whenever it is true for a real normed vector space that space must be an inner product space 9 10 For other types of metric space the inequality may or may not be valid A space in which it holds is called Ptolemaic For instance consider the four vertex cycle graph shown in the figure with all edge lengths equal to 1 The sum of the products of opposite sides is 2 However diagonally opposite vertices are at distance 2 from each other so the product of the diagonals is 4 bigger than the sum of products of sides Therefore the shortest path distances in this graph are not Ptolemaic The graphs in which the distances obey Ptolemy s inequality are called the Ptolemaic graphs and have a restricted structure compared to arbitrary graphs in particular they disallow induced cycles of length greater than three such as the one shown 11 The Ptolemaic spaces include all CAT 0 spaces and in particular all Hadamard spaces If a complete Riemannian manifold is Ptolemaic it is necessarily a Hadamard space 12 Inner product spaces editSee also Polarization identity Suppose that displaystyle cdot nbsp is a norm on a vector space X displaystyle X nbsp Then this norm satisfies Ptolemy s inequality x y z y z x x z y for all vectors x y z displaystyle x y z y z x geq x z y qquad text for all vectors x y z nbsp if and only if there exists an inner product displaystyle langle cdot cdot rangle nbsp on X displaystyle X nbsp such that x 2 x x displaystyle x 2 langle x x rangle nbsp for all vectors x X displaystyle x in X nbsp 13 Another necessary and sufficient condition for there to exist such an inner product is for the norm to satisfy the parallelogram law x y 2 x y 2 2 x 2 2 y 2 for all vectors x y displaystyle x y 2 x y 2 2 x 2 2 y 2 qquad text for all vectors x y nbsp If this is the case then this inner product will be unique and it can be defined in terms of the norm by using the polarization identity See also editGreek mathematics Mathematics of Ancient Greeks Parallelogram law The sum of the squares of the 4 sides of a parallelogram equals that of the 2 diagonals Polarization identity Formula relating the norm and the inner product in a inner product space Ptolemy 2nd century Roman mathematician astronomer geographer Ptolemy s table of chords 2nd century AD trigonometric table Ptolemy s theorem Relates the 4 sides and 2 diagonals of a quadrilateral with vertices on a common circleReferences edit a b Schoenberg I J 1940 On metric arcs of vanishing Menger curvature Annals of Mathematics Second Series 41 4 715 726 doi 10 2307 1968849 JSTOR 1968849 MR 0002903 Steele J Michael 2004 Exercise 4 6 Ptolemy s Inequality The Cauchy Schwarz Master Class An Introduction to the Art of Mathematical Inequalities MAA problem books Cambridge University Press p 69 ISBN 9780521546775 Alsina Claudi Nelsen Roger B 2009 6 1 Ptolemy s inequality When Less is More Visualizing Basic Inequalities Dolciani Mathematical Expositions vol 36 Mathematical Association of America pp 82 83 ISBN 9780883853429 Apostol 1967 attributes the inversion based proof to textbooks by R A Johnson 1929 and Howard Eves 1963 a b Stankova Zvezdelina Rike Tom eds 2008 Problem 7 Ptolemy s Inequality A Decade of the Berkeley Math Circle The American Experience MSRI Mathematical Circles Library vol 1 American Mathematical Society p 18 ISBN 9780821846834 a b Apostol 1967 Silvester John R 2001 Proposition 9 10 Ptolemy s theorem Geometry Ancient and Modern Oxford University Press p 229 ISBN 9780198508250 Zhu Hanlin 1984 68 25 A Tetrahedron Inequality The Mathematical Gazette 68 445 200 202 doi 10 2307 3616345 ISSN 0025 5572 a b Giles J R 2000 Exercise 12 Introduction to the Analysis of Normed Linear Spaces Australian Mathematical Society lecture series vol 13 Cambridge University Press p 47 ISBN 9780521653756 Schoenberg I J 1952 A remark on M M Day s characterization of inner product spaces and a conjecture of L M Blumenthal Proceedings of the American Mathematical Society 3 6 961 964 doi 10 2307 2031742 JSTOR 2031742 MR 0052035 Howorka Edward 1981 A characterization of Ptolemaic graphs Journal of Graph Theory 5 3 323 331 doi 10 1002 jgt 3190050314 MR 0625074 Buckley S M Falk K Wraith D J 2009 Ptolemaic spaces and CAT 0 Glasgow Mathematical Journal 51 2 301 314 doi 10 1017 S0017089509004984 MR 2500753 Apostol Tom M 1967 Ptolemy s Inequality and the Chordal Metric Mathematics Magazine 40 5 233 235 doi 10 2307 2688275 JSTOR 2688275 MR 0225213 Retrieved from https en wikipedia org w index php title Ptolemy 27s inequality amp oldid 1184326448, wikipedia, wiki, book, books, library,

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