DOCSLIB.ORG

American Mathematical Monthly Geometry Problems 1894 –

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
American Mathematical Monthly Geometry Problems 1894 – YIU : Problems in Elementary Geometry 1 American Mathematical Monthly Geometry Problems 1894 – Vis171. (Marcus Baker) In a traingle ABC, the center of the circumscribed circle is O, the center of the inscribed circle is I, and the orthocenter is H. Knowing the sides of the triangle OIH, determine the sides of triangle ABC. Solution by W.P. Casey: Let N be the nine-point center. From IN = R − 2 − 2 r and OI = R(R 2r), R and r can be determined. The circumcircle and the incircle, and the nine-point circle, can all be constructed. Then, Casey wrote, “[i]t only remains to find a point C in the circumcircle of ABC so that the tangent CA CA to circle I may be bisected by the circle N in the point S, which is easily done”. [sic] The construction of ABC from OIH cannot be effected by ruler and compass in general. Casey continued to derive the cubic equation with roots cos α,cosβ,cosγ, and coefficients in terms of R, r,and := OH,namely, r 4(R + r)2 − (2 +3R2) R2 − 2 x3 − (1 + )x2 + x − =0. R 8R2 8R2 Given triangle OIH,letN be the midpoint of OH. Construct the circle through N tangent to OI at O.ExtendIN to intersect this circle again at M. The diameter of the circumcircle is equal to the length of IM.From this, the circumcircle, the nine-point circle, and the incircle can be con- structed. Now, it remains to select a point X on the nine point circle so that the perpendicular to OX is tangent to the incircle. This is in general not constructible. YIU : Problems in Elementary Geometry 2 √ √ √ Here is√ an example: Let OI =2 2α, OH = 42α,andIH = 15α, where α = 17. Then s − a, s − b, s − c are the roots of the equation x3 − 34x2 +172x − 2 · 172 =0. The roots of this equation are inconstructible. Vis186. (Marcus Baker) (Malfatti circles) Inscribe in any plane triangle three circles each tangent to two sides and the other two circles. Three solutions were published. The second one, by U. Jesse Knisely, contains a construction: The third solution, by E. B. Seitz, 1 gives the radii of the Malfatti circles as (1 + tan β )(1 + tan γ ) 4 4 · r x = α , 1+tan 4 2 and analogous expressions for the other two. Vis52. (James McLaughlin) (Inverse Malfatti problem) Three circles, radii p, q, r,aredrawninatriangle, each circle touching the other two and two sides of the triangle. Find the sides of the triangle. 1The very first issue of the Monthly contains a biography of Seitz, written by Finkel. YIU : Problems in Elementary Geometry 3 Solution by E.B.Seitz: write σ = p + q + r. √ √ √ √ √ √ √ √ √ pσ +(p( p + q + r) − pqr) σ − pqr( q + r − p) a = √ √ √ √ √ √ √ √ (q + r)2. (p q + q p + pqσ − r σ)(p r + r p + prσ − q σ) Vis289. (Christine Ladd) If R is the radius of the circumscribed circle of a triangle ABC, r the radius of the inscribed circle, p the radius of the circle inscribed in the orthic triangle, I the center of the inscribed circle of the triangle ABC,andQ the center of the circle inscribed in the triangle formed by joining the midpoints of the sides of ABC, show that 1 QI2 = . 2(7Rp − 6Rr +3r2 +2R2) This certainly is not right! The correct formula should be 1 QI2 = (2Rp − 6Rr +3r2 +2R2). 2 Q is the Spieker center X10 and 1 QI2 = (−a3 +2a2(b + c) − 9abc). 8s IG 2 Also, IX10 = 3 .Now, − 3 2 − − 3 − 2 − 2 ( a +2a (b + c) 9abc)= s1 +5s1s2 18s3 =2s(5r 16Rr + s ). 2 1 2 − 2 Therefore, QI = 4 (5r 16Rr + s ). YIU : Problems in Elementary Geometry 4 YZ Now, for the orthic triangle, sin α =2R cos α. This means that YZ = R sin 2α. The semiperimeter of the orthic triangle is therefore 1 abc 4·R s = R(sin 2α+sin 2β+sin 2γ)=2R sin α sin β sin γ = = = . 2 4R2 4R2 R Also, =2cosα cos β cos γ. The inradius of the orthic triangle is p = =2R cos α cos β cos γ. s Now, (b2 + c2 − a2)(c2 + a2 − b2)(a2 + b2 − c2) cos α cos β cos γ = 8a2b2c2 − 6 4 − 2 2 − 3 − 2 ( s1 +6s1s2 8s1s2 8s1s3 +16s1s2s3 8s3 = 2 8s3 32r2s2[s2 − (2R + r)2] = 8(4Rrs)2 s2 − (2R + r)2 = . 8R2 s2−(2R+r)2 Therefore, p = 4R . s2 =(2R + r)2 +4Rp. Finally, 1 QI2 = (5r2 − 16Rr + s2) 4 1 = [5r2 − 16Rr +(2R + r)2 +4Rp] 4 1 = [6r2 − 12Rr +4R2 +4Rp] 4 1 = (2Rp − 6Rr +3r2 +2R2). 2 YIU : Problems in Elementary Geometry 5 VIS 274. If the midpoints of three sides of a triangle are joined with the opposite vertices and R1,...,R6 are the radii of the circles circumscribed about the 6 triangles so formed, and r1, r2, ..., r6 the radii of the circles inscribed in these triangles. prove that R1R3R5 = R2R4R6 and 1 1 1 1 1 1 + + = + + . r1 r3 r5 r2 r4 r6 VIS 282 (W.P.Casey) Let X, Y , Z be the traces of the incenter. Construct circles through I and with centers at X, Y , Z. The sum of the reciprocals of the radii of all the circles touching these circles is equal to four times the reciprocal of the inradius. G1.941.S941. (B.F.Finkel) Show that the bisectors of the angles formed by producing the sides of an inscribed quadrilateral intersect each other at right angles. G2.941.S942;943. (From Bowser’s Trigonometry) Show that π 2 · 4 · 6 · 8 · 10 ··· 2 = , 2 1 · 3 · 5 · 7 · 9 ··· Wallis’ expression for π. YIU : Problems in Elementary Geometry 6 P.H. Philbrick pointed out that this expression was not correct. It should be π 2 · 4 · 6 · 8 · 10 ···(2n) 2 1 = · . 2 1 · 3 · 5 · 7 · 9 ···(2n − 1) 2n +1 G3.941. (From Todhunter’s Trigonometry)IfA be the area of the circle inscribed in a triangle, A1, A2, A3 the ares of the escribed circles, show that 1 1 1 1 √ = √ + √ + √ . A A1 A2 A3 G4.941.S943. (From Todhunter’s Trigonometry) Three circles whose radii are a, b,andc touch each other externally; prove that the tangents at the points of contact meet in a point whose distance from any one of them is abc . a + b + c G5.941.S943. (Adolf Bailoff) If from a variable point in the base of an isosceles triangle, perpendiculars are drawn to the sides, the sum of the perpendiculars is constant and equal to the perpendicular let fall from either extremity of the base to the opposite side. YIU : Problems in Elementary Geometry 7 G6.941.S94:159–160. (Earl D. West) Having given the sides 6, 4, 5, and 3 respectively of a trapezium, inscribe in a circle, to find the diameter of the circle. [Note: trapezium means quadrilateral]. G7.941.S94:160. (William Hoover) Through each point of the straight line x = my + h isdrawnachordofthe parabola y2 =4ax, which is bisected in the point. Prove that this chord touches the parabola (y − 2mn)2 =8a(x − h). G8.941.S944. (Adolf Bailoff) If the two exterior angles at the base of a triangle are equal, the triangle is isosceles. G9.941.S94:160–161. (J.C.Gregg) Two circles intersect in A and B. Through A two lines CAE and DAF are drawn, each passing through a center and terminated by the circumferences. Show that CA · AE = DA · AF . (Euclid) G10.941.S94:161. (Eric Doolittle) If MN be any plane, and A and B any point without the plane, to find a point P , in the plane, such that AP + PB shall be a minimum. G11.941. (Lecta Miller) A gentleman’s residence is at the center of his circular farm containing a = 900 acres. He gives to each of his m = 7 children an equal circular farm as large as can be made within the original farm; and he retains as large a circular farm of which his residence is the center, as can be made after the distribution. Required the area of the farms made. G12.S94:198–199. (J.F.W.Scheffer) Let OA and OB represent two variable conjugate semi - diameters of the ellipse x2 y2 + =1. a2 b2 YIU : Problems in Elementary Geometry 8 On the chord AB as a side describe an equilateral triangle ABC.Findthe locus of C. G13.941. (Henry Heaton) Through two given points to pass four spherical surfaces tangent to two given spheres. G14.S94:232–233;268–269. (Henry Heaton) Through a given point to draw four circles tangent to two given circles. G15.S94:233–234. (Issac L. Beverage) A man starts from the center of a circular 10 acre field and walks due north a certain distance, then turns and walks south - west till he comes to the circumference, walking altogether 40 rods. How far did he walk before making the turn? G16.941. (H.C.Whitaker) Three lights of intensities 2, 4, and 5 are placed respectively at points the coordinates of which are (0, 3), (4, 5) and (9, 0). Find a point in the plane of the lights equally illuminated by all of them. G17.942:S94:269. (Robert J. Aley) Draw a circle bisecting the circumference of three given circles. G18.942.S94:271. (Henry Heaton) Through two given points to draw two circles tangnet to a given circle.
Load more

Recommended publications
  • Downloaded from Bookstore.Ams.Org 30-60-90 Triangle, 190, 233 36-72
    Index 30-60-90 triangle, 190, 233 intersects interior of a side, 144 36-72-72 triangle, 226 to the base of an isosceles triangle, 145 360 theorem, 96, 97 to the hypotenuse, 144 45-45-90 triangle, 190, 233 to the longest side, 144 60-60-60 triangle, 189 Amtrak model, 29 and (logical conjunction), 385 AA congruence theorem for asymptotic angle, 83 triangles, 353 acute, 88 AA similarity theorem, 216 included between two sides, 104 AAA congruence theorem in hyperbolic inscribed in a semicircle, 257 geometry, 338 inscribed in an arc, 257 AAA construction theorem, 191 obtuse, 88 AAASA congruence, 197, 354 of a polygon, 156 AAS congruence theorem, 119 of a triangle, 103 AASAS congruence, 179 of an asymptotic triangle, 351 ABCD property of rigid motions, 441 on a side of a line, 149 absolute value, 434 opposite a side, 104 acute angle, 88 proper, 84 acute triangle, 105 right, 88 adapted coordinate function, 72 straight, 84 adjacency lemma, 98 zero, 84 adjacent angles, 90, 91 angle addition theorem, 90 adjacent edges of a polygon, 156 angle bisector, 100, 147 adjacent interior angle, 113 angle bisector concurrence theorem, 268 admissible decomposition, 201 angle bisector proportion theorem, 219 algebraic number, 317 angle bisector theorem, 147 all-or-nothing theorem, 333 converse, 149 alternate interior angles, 150 angle construction theorem, 88 alternate interior angles postulate, 323 angle criterion for convexity, 160 alternate interior angles theorem, 150 angle measure, 54, 85 converse, 185, 323 between two lines, 357 altitude concurrence theorem,
    [Show full text]
  • An Innovative Analysis to Develop New Theorems on Irregular Polygon
    International Journal of Physics and Mathematical Sciences ISSN: 2277-2111 (Online) An Online International Journal Available at http://www.cibtech.org/jpms.htm 2013 Vol. 3 (1) January-March, pp.73-81/Kalaimaran Research Article AN INNOVATIVE ANALYSIS TO DEVELOP NEW THEOREMS ON IRREGULAR POLYGON *Kalaimaran Ara Construction & Civil Maintenance Unit, Central Food Technological Research Institute, Mysore-20, Karnataka, India *Author for Correspondence ABSTRACT The irregular Polygon is a four sided polygon of two dimensional geometrical figures. The triangle, square, rectangle, tetragon, pentagon, hexagon, heptagon, octagon, nonagon, dodecagon, parallelogram, rhombus, rhomboid, trapezium or trapezoidal, kite and dart are the members of the irregular polygon family. A polygon is a two dimensional example of the more general prototype in any number of dimensions. However the properties are varied from one to another. The author has attempted to develop two new theorems for the property of irregular polygon for a point anywhere inside of the polygon with necessary illustrations, appropriate examples and derivation of equations for better understanding. Key Words: Irregular Polygon, Triangle, Right-angled triangle, Perpendicular and Vertex INTRODUCTION Polygon (Weisstein, 2003) is a closed two dimensional figure formed by connecting three or more straight line segments, where each line segment end connects to only one end of two other line segments. Polygon is one of the most all-encompassing shapes in two- dimensional geometry. The sum of the interior angles is equal to 180 degree multiplied by number of sides minus two. The sum of the exterior angles is equal to 360 degree. From the simple triangle up through square, rectangle, tetragon, pentagon, hexagon, heptagon, octagon, nonagon, dodecagon (Weisstein, 2003,) and beyond is called n-gon.
    [Show full text]
  • Some Relations and Properties Concerning Tangential Polygons
    View metadata, citation and similar papers at core.ac.uk brought to you by CORE Mathematical Communications 4(1999), 197-206 197 Some relations and properties concerning tangential polygons Mirko Radic´∗ Abstract. The k-tangential polygon is defined, and some of its properties are proved. Key words: k-tangential polygon AMS subject classifications: 51E12 Received October 10, 1998 Accepted June 7, 1999 1. Preliminaries A polygon with the vertices A1, ..., An (in this order) will be denoted by A1...An. The lengths of the sides of the polygon A1...An will be denoted by |A1A2|, ..., |AnA1| or a1, ..., an. The interior angle at the vertex Ai will be denoted by αi or ∠Ai, i.e. ∠Ai = ∠An−1+iAiAi+1,i=1, ..., n (0 <αi <π). (1) Of course, indices are calculated modulo n. A polygon A = A1...An is a tangential polygon if there exists a circle C such that each side of A is on a tangent line of C. Definition 1. Let A = A1...An be a tangential polygon, and let k be a positive ≤bn−1 c ≤ n−1 ≤ n−2 integer such that k 2 , that is, k 2 if n is odd and k 2 if n is even. Then the polygon A will be called a k-tangential polygon if any two of its consecutive sides have only one point in common, and if there holds π β + ···+ β =(n − 2k) , (2) 1 n 2 where 2βi = ∠Ai, i =1, ..., n. Consequently, a tangential polygon A is k-tangential if n X ϕi =2kπ, i=1 where ϕi = ∠AiCAi+1 and C is the centre of the circle inscribed into the polygon A.
    [Show full text]
  • Arxiv:1712.00299V1 [Math.GT]
    POLYGONS WITH PRESCRIBED EDGE SLOPES: CONFIGURATION SPACE AND EXTREMAL POINTS OF PERIMETER JOSEPH GORDON, GAIANE PANINA, YANA TEPLITSKAYA Abstract. We describe the configuration space S of polygons with pre- scribed edge slopes, and study the perimeter as a Morse function on S. We characterize critical points of (these areP tangential polygons) and compute their Morse indices. ThisP setup is motivated by a number of re- sults about critical points and Morse indices of the oriented area function defined on the configuration space of polygons with prescribed edge lengths (flexible polygons). As a by-product, we present an independent computa- tion of the Morse index of the area function (obtained earlier by G. Panina and A. Zhukova). 1. Introduction Consider the space L of planar polygons with prescribed edge lengths1 and the oriented area as a Morse function defined on it. It is known that gener- ically: A L is a smooth closed manifold whose diffeomorphic type depends on • the edge lengths [1, 2]. The oriented area is a Morse function whose critical points are cyclic • configurations (thatA is, polygons with all the vertices lying on a cir- cle), whose Morse indices are known, see Theorem 2, [3, 5, 6]. The Morse index depends not only on the combinatorics of a cyclic poly- arXiv:1712.00299v1 [math.GT] 1 Dec 2017 gon, but also on some metric data. Direct computations of the Morse index proved to be quite involved, so the existing proof comes from bifurcation analysis combined with a number of combinatorial tricks. Bifurcations of are captured by cyclic polygons P whose dual poly- • gons P ∗ have zeroA perimeter [5]; see also Lemma 4.
    [Show full text]
  • (Theorem 1) Is Proved
    Rad HAZU Volume 503 (2009), 41–54 ABOUT ONE RELATION CONCERNING TWO CIRCLES MIRKO RADIC´ AND ZORAN KALIMAN Abstract. This article can be considered as an appendix to the article [1]. Here the article [1] is extended to the cases when one circle is outside of the other and when circles are intersecting. 1. Preliminaries In [1] the following theorem (Theorem 1) is proved: Let C1 and C2 be any given two circles such that C1 is inside of the C2 and let A1 , A2 , A3 be any given three different points on C2 such that there are points T1 and T2 on C1 with properties |A1A2| = t1 +t2, |A2A3| = t2 +t3, (1) where t1 = |A1T1|, t2 = |T1A2|, t3 = |T2A3|.Then 2rR |A A | =(t +t ) , (2) 1 3 1 3 R2 − d2 where r = radius of C1 , R = radius of C2 , d = |IO|, I is the center of C1 , O is center of C2 .(SeeFigure1.) In short about the proof of this theorem. First the following lemma is proved. It t1 is given then t2 can be calculated using the expression √ t (R2 − d2) ± D (t ) = 1 1 (3a) 2 1,2 2 + 2 r t1 where = 2( 2 − 2)2 +( 2 + 2) 2 2 − 2 2 − ( 2 + 2 − 2)2 . D1 t1 R d r t1 4R d r t1 R d r (3b) The values (t2)1,2 given by (3) are solutions of the equation ( 2 + 2) 2 − ( 2 − 2)+ 2 2 − 2 2 +( 2 + 2 − 2)2 = . r t1 t2 2t1t2 R d r t1 4R d R d r 0 (4) Mathematics subject classification (2000): 51M04.
    [Show full text]
  • Some Relations Concerning K-Chordal and K-Tangential Polygons
    Mathematical Communications 7(2002), 21-34 21 Some relations concerning k-chordal and k-tangential polygons Mirko Radic´∗ Abstract. In papers [6] and [7] the k-chordal and the k-tangential polygons are defined and some of their properties are proved. In this paper we shall consider some of their other properties. Theorems 1-4 are proved. Key words: geometrical inequalities, k-chordal polygon, k-tangential polygon AMS subject classifications: 51E12, 52A40 Received October 8, 2001 Accepted April 4, 2002 1. Preliminaries A polygon with vertices A1 ...An (in this order) will be denoted by A1 ...An and the lengths ofthe sides of A1 ...An will be denoted by a1,... ,an,whereai = | AiAi+1 |, i =1, 2,... ,n. For the interior angle at the vertex Ai we write αi or ∠Ai, i.e. ∠Ai = ∠An−1+iAiAi+1,i=1,... ,n. Ofcourse, indices are calculated modulo n. For convenience we list some definitions given in [6] and [7]. Definition 1. Let A = A1 ...An be a chordal polygon and let C be its circum- circle. By SAi and SAi we denote the semicircles of C such that SAi ∪ SAi = C, Ai ∈ SAi ∩ SAi . The polygon A is said to be of the first kind if the following is fulfilled: 1. all vertices A1 ...An do not lie on the same semicircle, 2. for every three consecutive vertices Ai,Ai+1,Ai+2 it holds Ai ∈ SAi+1 ⇒ Ai+2 ∈ SAi+1 3. any two consecutive vertices Ai,Ai+1 do not lie on the same diameter. Definition 2. Let A = A1 ...An be a chordal polygon and let k be a positive integer.
    [Show full text]
  • Topics in Elementary Geometry
    Topics in Elementary Geometry Second Edition O. Bottema (deceased) Topics in Elementary Geometry Second Edition With a Foreword by Robin Hartshorne Translated from the Dutch by Reinie Erne´ 123 O. Bottema Translator: (deceased) Reinie Ern´e Leiden, The Netherlands [email protected] ISBN: 978-0-387-78130-3 e-ISBN: 978-0-387-78131-0 DOI: 10.1007/978-0-387-78131-0 Library of Congress Control Number: 2008931335 Mathematics Subject Classification (2000): 51-xx This current edition is a translation of the Second Dutch Edition of, Hoofdstukken uit de Elementaire Meetkunde, published by Epsilon-Uitgaven, 1987. c 2008 Springer Science+Business Media, LLC All rights reserved. This work may not be translated or copied in whole or in part without the written permission of the publisher (Springer Science+Business Media, LLC, 233 Spring Street, New York, NY 10013, USA), except for brief excerpts in connection with reviews or scholarly analysis. Use in connec- tion with any form of information storage and retrieval, electronic adaptation, computer software, or by similar or dissimilar methodology now known or hereafter developed is forbidden. The use in this publication of trade names, trademarks, service marks, and similar terms, even if they are not identified as such, is not to be taken as an expression of opinion as to whether or not they are subject to proprietary rights. Printed on acid-free paper 987654321 springer.com At school I was good in mathematics; now I discovered that I found the so-called higher mathematics – differential and integral calculus – easier than the complicated (but elementary) plane geometry.
    [Show full text]
  • 3Doodler Geometry: Pyramids
    3Doodler EDU 3Doodler Geometry: Pyramids Suitable Ages: Suitable for ages 14+ Skill Level: Basic Materials Required: • 3Doodler 2.0: At a minimum, one 3Doodler per group (six groups per class); if more 3Doodlers are available, one for every one to two students is advisable • 3Doodler PLA or ABS strands: 3 strands per 3Doodler • Pyramid Stencils (N.B.: If PLA is used, it is advisable to apply a layer of masking tape over the stencil to ensure that the shapes can be peeled off the stencil with ease) • The Pyramid Worksheet (pages 16-19) Duration: This classroom activity will take between two and three hours, which can be divided between a number of classroom sessions Instructional Video: Instructional videos showing how to build the Pyramids 1 & 4 of this activity are available at: YouTube: https://youtu.be/f0wQQKNY51w and https://youtu.be/coKS6OJh8WU Vimeo: https://vimeo.com/140039345 and https://vimeo.com/140039344 Dropbox: https://www.dropbox.com/s/hvpr8mcv6f135yi/Example%20Pyramid%201.mpeg?dl=0 and https://www.dropbox.com/s/xf004dw7o4lzcwq/Example%20Pyramid%204.mpeg?dl=0 Written by: Linda Giampieretti Part of the “Fascinating World of Geometric Forms” Project Page 1 of 23 Contents Objective 3 Activity 4 Sequence & Pacing 6 Striving Students 6 Accelerated Students 6 Evaluation Strategies 6 Evaluation Rubric 7 Reference Materials 8 Stencil: Pyramid 1 10 Stencil: Pyramid 2 11 Stencil: Pyramid 3 12 Stencil: Pyramid 4 13 Stencil: Pyramid 5 14 Stencil: Pyramid 6 15 Pyramid Worksheet 16 Worksheet Answer Key 19 Additional Resources 22 Page 2 of 23 Objective Triangles, and in turn, pyramids, form the basis for much of the structural strength in modern architecture and engineering.
    [Show full text]
  • Some Relations and Properties Concerning Tangential Polygons
    Mathematical Communications 4(1999), 197-206 197 Some relations and properties concerning tangential polygons Mirko Radic´∗ Abstract. The k-tangential polygon is defined, and some of its properties are proved. Key words: k-tangential polygon AMS subject classifications: 51E12 Received October 10, 1998 Accepted June 7, 1999 1. Preliminaries A polygon with the vertices A1, ..., An (in this order) will be denoted by A1...An. The lengths of the sides of the polygon A1...An will be denoted by |A1A2|, ..., |AnA1| or a1, ..., an. The interior angle at the vertex Ai will be denoted by αi or ∠Ai, i.e. ∠Ai = ∠An−1+iAiAi+1,i=1, ..., n (0 <αi <π). (1) Of course, indices are calculated modulo n. A polygon A = A1...An is a tangential polygon if there exists a circle C such that each side of A is on a tangent line of C. Definition 1. Let A = A1...An be a tangential polygon, and let k be a positive ≤bn−1 c ≤ n−1 ≤ n−2 integer such that k 2 , that is, k 2 if n is odd and k 2 if n is even. Then the polygon A will be called a k-tangential polygon if any two of its consecutive sides have only one point in common, and if there holds π β + ···+ β =(n − 2k) , (2) 1 n 2 where 2βi = ∠Ai, i =1, ..., n. Consequently, a tangential polygon A is k-tangential if n X ϕi =2kπ, i=1 where ϕi = ∠AiCAi+1 and C is the centre of the circle inscribed into the polygon A.
    [Show full text]
  • Robbie Robinson, Professor of Mathematics, George Washington University
    Robbie Robinson, Professor of Mathematics, George Washington University Georgetown Math Club March 1, 2016 Leonardo da Vinci, illustrations for Luca Pacioli’s 1509 book The Divine Proportion. From: http://www.georgehart.com/virtual-polyhedra/leonardo.html Melencolia I Albrecht Dürer, 1514 Anatoly Fomenko 1945- Nicholas Neufchatel, Johannes Neudorfer and son 1561 M. C. Escher Stars Salvador Dali, The Last Supper, 1955 Tony Robbin, 2000-10 http://tonyrobbin.home.att.net/work.htm The 2-dimensional case… Ehrhard Bohne, 2000 http://www.math-inf.uni-greifswald.de/mathematik+kunst/mathematiker_bohne.html\ Pas de Deux, Nat Friedman, Fractal Stone Print http://www.albany.edu/~artmath/cetl/am97/ Theorem 1. Let A1, A2, …, An be the interior angles of a polygon. Let o Sn=A1+A2+…+An. Then Sn=180 (n-2). A2 A3 A4 A1 Example. For n=4 we have o o o o. A1+A2+A3+A4 = 180 (n-2)=180 (4-2)=180 (2)=360 Lemma. Let B1, B2, …, Bn be the exterior o angles of a polygon. Then B1+B2+…+Bn= 360 B2 B3 B1 B4 Note: this does not depend on the number of sides! n Sn Rn Sn = 180(n-2) 3 180 60 � � − 2 � = " = 180 4 360 90 " � � 5 540 108 Rn is the angle of a regular n-gon 6 720 120 �" → 180 as � → ∞ 7 900 128.5… 8 1080 135 9 1260 140 10 1440 144 Schlflaly symbol {n,k}={n/k}={9,3} � − 2� � = 180 " � Vertex e.g. Edge Dodecahedron Face Vertices Dihedral angle (plural) Vertex: interior angle/angle deficit wire frame or stick figure solid (perspective) Schlegel web diagram diagram Convex polyhedra projected to sphere=tiling of sphere.
    [Show full text]
  • Inscribed Angles and Quadrilaterals Worksheet Answers Nano
    Inscribed Angles And Quadrilaterals Worksheet Answers Sapient and heterodyne John-Patrick smoke-dry her emigrants tabulating or suds aliunde. Gilded and oftenmetaphysical recalls some Bennie Brunei covings deservedly her mangrove or oversteer hewings readably. or photoengraved whence. Fibroblastic and octantal Abbot Right angles for an inscribed angles quadrilaterals worksheet will allow the fourth set of Correct measure on and inscribed quadrilaterals answers for firefox because its sides are an inscribed angles are coming to spare to operate this problem. As a bus, inscribed angles quadrilaterals worksheet answers using the printing of a question is a circle and the document. Incorrect answer keys, inscribed angles answers for a unit on the google drive traffic and examples of notes are the instructions. Software please see the inscribed angles and worksheet answers for remote learning and its event handler order is your identity as possible after exploring various square. Online tutoring and angles worksheet answers using the congruent parts, you to use with it of a unique website? Quadrilateral theorem in finding angles and worksheet you the issue. Numbers and angles quadrilaterals answers by composing into triangles are supplementary is: the geometric shape and inside inscribed triangles and a set your traffic? Third set of worksheets encloses charts, inscribed quadrilaterals inscribed in our teacher answer is. Fully annotated typed answer, angles quadrilaterals and link to find the parallelograms worksheets. Easily digestible for the angles and quadrilaterals worksheet answers are of this is a header and link. Riddle practice and inscribed angles quadrilaterals answers for your workforce and triangle. Binder geometry notes is inscribed angles quadrilaterals worksheet answers for free information about central angles with your choices at properties; employing the parallelograms with circles.
    [Show full text]
  • Semidefinite Programming for Optimizing Convex Bodies Under
    Semidefinite programming for optimizing convex bodies under width constraints T´erence Bayen1, Didier Henrion2,3 October 22, 2010 Abstract We consider the problem of minimizing a functional (like the area, perimeter, surface) within the class of convex bodies whose support functions are trigonometric polynomials. The convexity constraint is transformed via the Fej´er-Riesz theorem on positive trigono- metric polynomials into a semidefinite programming problem. Several problems such as the minimization of the area in the class of constant width planar bodies, rotors and space bodies of revolution are revisited. The approach seems promising to investigate more difficult optimization problems in the class of three-dimensional convex bodies. Keywords: convexity, optimization, semidefinite programming, support function. AMS Subject Classification: 49M27,90C22,52C05 1 Introduction Many optimization problems involve convexity constraints. Such constraints naturally appear in the framework of geometric optimization problems, where the underlying admissible class is the set of convex bodies in Euclidean space. This paper aims to tackle the issue of a certain class of planar geometric optimization problems via semidefinite programming. A convex body can be parametrized by its support function defined by homogeneity on the unit hypersphere. The convexity constraint amounts to the non-negativity of the principal radii of curvature of the boundary of the body (if they are defined). For the planar case, the convexity constraint is equivalent to the non-negativity of the radius of curvature of the boundary of the body, easily expressed via the support function. A reformulation of the con- vexity constraint allows the use of the calculus of variation and optimal control theory to treat 1Institut de Math´ematiques et de Mod´elisation de Montpellier, Universit´e Montpellier 2, Case Courrier 051, Place Eug`eneBataillon, 34095 Montpellier Cedex, France.
    [Show full text]