Poncelet's closure theorem

Poncelet's closure theorem Illustration of Poncelet's porism for n = 3, a triangle that is inscribed in one circle and circumscribes another.

In geometry, Poncelet's closure theorem, also known as Poncelet's porism, states that whenever a polygon is inscribed in one conic section and circumscribes another one, the polygon must be part of an infinite family of polygons that are all inscribed in and circumscribe the same two conics.[1][2] It is named after French engineer and mathematician Jean-Victor Poncelet, who wrote about it in 1822; however, the triangular case was discovered significantly earlier, in 1746 by William Chapple.[3] Poncelet's porism can be proved by an argument using an elliptic curve, whose points represent a combination of a line tangent to one conic and a crossing point of that line with the other conic.

Contents 1 Statement 2 Proof sketch 3 See also 4 References 5 External links Statement Let C and D be two plane conics. If it is possible to find, for a given n > 2, one n-sided polygon that is simultaneously inscribed in C (meaning that all of its vertices lie on C) and circumscribed around D (meaning that all of its edges are tangent to D), then it is possible to find infinitely many of them. Each point of C or D is a vertex or tangency (respectively) of one such polygon.

If the conics are circles, the polygons that are inscribed in one circle and circumscribed about the other are called bicentric polygons, so this special case of Poncelet's porism can be expressed more concisely by saying that every bicentric polygon is part of an infinite family of bicentric polygons with respect to the same two circles.[4]: p. 94  Proof sketch View C and D as curves in the complex projective plane P2. For simplicity, assume that C and D meet transversely (meaning that each intersection point of the two is a simple crossing). Then by Bézout's theorem, the intersection C ∩ D of the two curves consists of four complex points. For an arbitrary point d in D, let ℓd be the tangent line to D at d. Let X be the subvariety of C × D consisting of (c,d) such that ℓd passes through c. Given c, the number of d with (c,d) ∈ X is 1 if c ∈ C ∩ D and 2 otherwise. Thus the projection X → C ≃ P1 presents X as a degree 2 cover ramified above 4 points, so X is an elliptic curve (once we fix a base point on X). Let {displaystyle sigma } be the involution of X sending a general (c,d) to the other point (c,d′) with the same first coordinate. Any involution of an elliptic curve with a fixed point, when expressed in the group law, has the form x → p − x for some p, so {displaystyle sigma } has this form. Similarly, the projection X → D is a degree 2 morphism ramified over the contact points on D of the four lines tangent to both C and D, and the corresponding involution {displaystyle tau } has the form x → q − x for some q. Thus the composition {displaystyle tau sigma } is a translation on X. If a power of {displaystyle tau sigma } has a fixed point, that power must be the identity. Translated back into the language of C and D, this means that if one point c ∈ C (equipped with a corresponding d) gives rise to an orbit that closes up (i.e., gives an n-gon), then so does every point. The degenerate cases in which C and D are not transverse follow from a limit argument.

See also Finding Ellipses Hartshorne ellipse Steiner's porism Tangent lines to circles References ^ Weisstein, Eric W. "Poncelet's Porism." From MathWorld--A Wolfram Web Resource. http://mathworld.wolfram.com/PonceletsPorism.html ^ King, Jonathan L. (1994). "Three problems in search of a measure". Amer. Math. Monthly. 101: 609–628. doi:10.2307/2974690. ^ Del Centina, Andrea (2016), "Poncelet's porism: a long story of renewed discoveries, I", Archive for History of Exact Sciences, 70 (1): 1–122, doi:10.1007/s00407-015-0163-y, MR 3437893 ^ Johnson, Roger A., Advanced Euclidean Geometry, Dover Publications, 2007 (orig. 1960). Bos, H. J. M.; Kers, C.; Oort, F.; Raven, D. W. "Poncelet's closure theorem". Expositiones Mathematicae 5 (1987), no. 4, 289–364. External links David Speyer on Poncelet's Porism D. Fuchs, S. Tabachnikov, Mathematical Omnibus: Thirty Lectures on Classic Mathematics Interactive applet by Michael Borcherds showing the cases n = 3, 4, 5, 6, 7, 8 (including the convex cases for n = 7, 8) made using GeoGebra. Interactive applet by Michael Borcherds showing Poncelet's Porism for a general Ellipse and a Parabola made using GeoGebra. Interactive applet by Michael Borcherds showing Poncelet's Porism for 2 general ellipses (order 3) made using GeoGebra. Interactive applet by Michael Borcherds showing Poncelet's Porism for 2 general ellipses (order 5) made using GeoGebra. Interactive applet by Michael Borcherds showing Poncelet's Porism for 2 general ellipses (order 6) made using GeoGebra. Java applet showing the exterior case for n = 3 at National Tsing Hua University. Article on Poncelet's Porism at Mathworld. Categories: Conic sectionsElliptic curves

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