New Constants Associated to Regular Tetrahedron and Cube

Similar documents
Parametric Solutions for a Nearly-Perfect Cuboid arxiv: v1 [math.nt] 9 Feb 2015

Sums of Squares of Distances in m-space

SYMMETRIES IN R 3 NAMITA GUPTA

ON THE PUZZLES WITH POLYHEDRA AND NUMBERS

BMT 2014 Symmetry Groups of Regular Polyhedra 22 March 2014

(1) Recap of Differential Calculus and Integral Calculus (2) Preview of Calculus in three dimensional space (3) Tools for Calculus 3

Vectors and Fields. Vectors versus scalars

Geometry. A. Right Triangle. Legs of a right triangle : a, b. Hypotenuse : c. Altitude : h. Medians : m a, m b, m c. Angles :,

Mathematical jewels that you may not have seen in school

Vectors Coordinate frames 2D implicit curves 2D parametric curves. Graphics 2008/2009, period 1. Lecture 2: vectors, curves, and surfaces

Basic Surveying Week 3, Lesson 2 Semester 2017/18/2 Vectors, equation of line, circle, ellipse

Symmetry. Professor Robert A. Wilson. 22nd July Queen Mary, University of London

Lecture 10: Multiple Integrals

1966 IMO Shortlist. IMO Shortlist 1966

Math Requirements for applicants by Innopolis University

ME 201 Engineering Mechanics: Statics

A Solution of a Tropical Linear Vector Equation

Elementary maths for GMT

2017 Harvard-MIT Mathematics Tournament

Vectors - Applications to Problem Solving

JAMAICA_ C.X.C. Course

2. Force Systems. 2.1 Introduction. 2.2 Force

POLYHEDRON PUZZLES AND GROUPS

Contents. MATH 32B-2 (18W) (L) G. Liu / (TA) A. Zhou Calculus of Several Variables. 1 Multiple Integrals 3. 2 Vector Fields 9

Chapter 9 Moment of Inertia

Tycho Brahe and Johannes Kepler

Traditional Mathematics in the Aomori Prefecture

VOLUME OF A TETRAHEDRON IN THE TAXICAB SPACE

The Golden Section, the Pentagon and the Dodecahedron

Definitions and Properties of R N

Math Precalculus I University of Hawai i at Mānoa Spring

Contents. D. R. Wilkins. Copyright c David R. Wilkins

The Story of a Research About the Nets of Platonic Solids with Cabri 3D: Conjectures Related to a Special Net Factor A Window for New Researches

12-neighbour packings of unit balls in E 3

Washington State Math Championship Mental Math Grades 5

What is a Galois field?

Math 461 Homework 8. Paul Hacking. November 27, 2018

How Do You Group It?

Math 461 Homework 8 Paul Hacking November 27, 2018

12.1. Cartesian Space

Wholemovement of the circle Bradford Hansen-Smith

The Droz-Farny Circles of a Convex Quadrilateral

INGENIERÍA EN NANOTECNOLOGÍA

Symmetry. PlayMath, Summer, 2018

USAC Colloquium. Bending Polyhedra. Andrejs Treibergs. September 4, Figure 1: A Rigid Polyhedron. University of Utah

4.Let A be a matrix such that A. is a scalar matrix and Then equals :

Math Precalculus I University of Hawai i at Mānoa Spring

The Geometric Aspect of Ternary Forms

Chapter 3: Inequalities, Lines and Circles, Introduction to Functions

Index. Excerpt from "Art of Problem Solving Volume 1: the Basics" 2014 AoPS Inc. / 267. Copyrighted Material

(Refer Slide Time: 2:08 min)

Symmetries and Polynomials

Descartes Circle Theorem, Steiner Porism, and Spherical Designs

22. On Steiner's Curvature-centroid. By Buchin SU, Sendai. (Received July 15, 1927.)

MATH 243 Winter 2008 Geometry II: Transformation Geometry Solutions to Problem Set 1 Completion Date: Monday January 21, 2008

The Sphere OPTIONAL - I Vectors and three dimensional Geometry THE SPHERE

5. Vector Algebra and Spherical Trigonometry (continued)

Roots of Unity, Cyclotomic Polynomials and Applications

THE MEAN MINKOWSKI MEASURES FOR CONVEX BODIES OF CONSTANT WIDTH. HaiLin Jin and Qi Guo 1. INTRODUCTION

Date: Tuesday, 19 November :00PM. Location: Museum of London

Advanced Ceramics for Strategic Applications Prof. H. S. Maiti Department of Mechanical Engineering Indian Institute of Technology, Kharagpur

On the Volume Formula for Hyperbolic Tetrahedra

NAEP Questions, Pre-Algebra, Unit 13: Angle Relationships and Transformations

Cyclic Central Configurations in the Four-Body Problem

COURSE SUMMARY FOR MATH 504, FALL QUARTER : MODERN ALGEBRA

17 Finite crystal lattice and its Fourier transform. Lattice amplitude and shape amplitude

Amorous Bugs and Pursuit Problems By Steven Schonefeld

Two small balls, each of mass m, with perpendicular bisector of the line joining the two balls as the axis of rotation:

The Distance Formula. The Midpoint Formula

BMOS MENTORING SCHEME (Senior Level) February 2011 (Sheet 5) Solutions

On finite congruence-simple semirings

1. Appendix A- Typologies

1. Vectors and Matrices

MAT 419 Lecture Notes Transcribed by Eowyn Cenek 6/1/2012

Statics: Lecture Notes for Sections

Solving PDEs Numerically on Manifolds with Arbitrary Spatial Topologies

n=0 ( 1)n /(n + 1) converges, but not

Prentice Hall Mathematics, Pre-Algebra 2007 Correlated to: Michigan Grade Level Content Expectations (Grades 8)

2016 OHMIO Individual Competition

f. D that is, F dr = c c = [2"' (-a sin t)( -a sin t) + (a cos t)(a cost) dt = f2"' dt = 2

Volume of n-dimensional ellipsoid

clear all format short

Vector Calculus, Maths II

JUST THE MATHS UNIT NUMBER INTEGRATION APPLICATIONS 10 (Second moments of an arc) A.J.Hobson

Calculus III (MAC )

Symmetric spherical and planar patterns

arxiv: v2 [math-ph] 24 Feb 2016

10.5 MOMENT OF INERTIA FOR A COMPOSITE AREA

Brief Review of Exam Topics

TS EAMCET 2016 SYLLABUS ENGINEERING STREAM

b) Rectangular box: length L, width W, height H, volume: V = LWH, cube of side s, V = s 3

The hyperbolic plane and a regular 24-faced polyhedron

DEFINITION OF MOMENTS OF INERTIA FOR AREAS, RADIUS OF GYRATION OF AN AREA

chapter 1 vector geometry solutions V Consider the parallelogram shown alongside. Which of the following statements are true?

SMT 2018 Geometry Test Solutions February 17, 2018

ANSWERS. CLASS: VIII TERM - 1 SUBJECT: Mathematics. Exercise: 1(A) Exercise: 1(B)

An eightfold path to E 8

ON A CHARACTERISATION OF INNER PRODUCT SPACES

Parallelograms inscribed in a curve having a circle as π 2 -isoptic

Hecke Groups, Dessins d Enfants and the Archimedean Solids

Transcription:

New Constants Associated to Regular Tetrahedron and Cube Mamuka Meskhishvili Abstract We consider the points on the sphere with center at the centroid of the regular tetrahedron and the cube. We prove that the sum of the fourth power distances from these points to the vertices of the regular tetrahedron is constant and in case of the cube the sums of the fourth and the sixth power distances are constant too. Keywords. Regular tetrahedron, cube, Platonic solid, sphere, centroid, constant sum of the square distances, constant sum of the fourth power distances, constant sum of the sixth power distances. 2010 AMS Classification. 51M04, 51N20, 51N35.

1 Introduction Consider any regular polygon (n-gon) and a point X on any circle with center at the centroid of the n-gon. Denote the vertices of the n-gon as P i. Then it follows S (2) = n d 2 (X, P i ), where S (2) is constant, i.e. the sum of the square distances d 2 (X, P i ) remains unchanged, when a point X moves on any circle with center at the centroid 1]. The case of the second power (square) distances admits a 3D-generalization. Furthermore, an analogous result is obtained for high dimensional space 2], but nothing is known if the powers of distances are more than 2. We consider the sums of even powers of distances S (2m) = n d 2m (X, P i ), when m > 1, for the regular tetrahedron (n = 4) and the cube (n = 8). General theorem on regular polyhedrons is known only for the second power sums. Consider a regular polyhedron with n vertices and an arbitrary point X on any sphere with center at the centroid O of the polyhedron. The sum of the square distances from X to the vertices of the polyhedron is constant and equals S (2) = n(l 2 + R 2 ), (1) where L is a radius of the sphere and R is a circumradius of the regular polyhedron. This result is easily obtained by using the properties of a scalar vector product: 2

S (2) = = n n d 2 2 (X, P i ) = XP i = n XO 2 + 2XO n ( n 2 n 2 OP i + OP i, XO + OP i ) 2 which gives us (1) because of XO 2 = L 2, n OP i = 0 and OP i 2 = R 2. The same equality holds if the n points are all at the same distance L from their centroid, even if they fo not form a regular polyhedron: that is the case, for instance, of a semiregular polyhedron. This method cannot be used for high powers, when m > 1, because from the definition of the scalar product only the second power of the vector is defined. Instead of vectors, the coordinate method can be used, which gives huge algebraic expressions and it is difficult to predict which of their surprising simplifications will occur. From my consideration, inefficiency of the scalar vector product and complex algebraic expressions are the reasons why the results of this article were not known till present. In the article we will prove, that results about regular triangle and square 3] admit 3D-generalization. In particular, the sum of the fourth power distances, from an arbitrary point on any sphere with center at the centroid of the regular tetrahedron to the vertices of the tetrahedron, is constant and in case of the cube the sums of the fourth and the sixth powers are constant too. 3

2 Regular Tetrahedron Introduce the Cartesian coordinate system so that the coordinates of the vertices of the regular tetrahedron are: P 1 (4t, 0, 0), ( ) P 2 2t, 2 3 t, 0, ( ) P 3 2t, 2 3 t, 0, ( ) P 4 0, 0, 4 2 t. The origin of the coordinate system is chosen to coincide with the centroid of the triangle P 1 P 2 P 3 and x and z axes pass through the vertices P 1 and P 4, respectively. Then the centroid of the tetrahedron is: O ( 0, 0, 2 t ). The sphere equation with center at the centroid and any radius L: x 2 + y 2 + ( z 2 t ) 2 = L 2. The circumradius of the tetrahedron: R = 3 2 t. The square distances from an arbitrary X(x, y, z) point to the vertices are: 4

d 2 (X, P 1 ) = (x 4t) 2 + y 2 + z 2, d 2 (X, P 2 ) = (x + 2t) 2 + ( y 2 3 t ) 2 + z 2, d 2 (X, P 3 ) = (x + 2t) 2 + ( y + 2 3 t ) 2 + z 2, d 2 (X, P 4 ) = x 2 + y 2 + ( z 4 2 t ) 2. The sum of the square distances: 4 S (2) = d 2 (X, P i ) = 4 x 2 + y 2 + ( z 2 t ) ] 2 + 18t 2 = 4(L 2 + R 2 ), which is (1). The sum of the fourth power distances: S (4) = ( (x 4t) 2 + y 2 + z 2) 2 + ((x + 2t) 2 + (y 2 3 t) 2 + z 2) 2 + ((x + 2t) 2 + (y + 2 3 t) 2 + z 2) 2 + ( x 2 + y 2 + (z 4 2 t) 2) 2. It is difficult to imagine that this algebraic expression can be expressed only in terms of L and R, but the plane case results 3] give us this hope. 5

Indeed: S (4) = (x 4t) 4 + y 4 + z 4 + (x + 2t) 4 + (y 2 3 t) 4 + z 4 + (x + 2t) 4 + (y + 2 3 t) 4 + z 4 + (z 4 2 t) 4 + x 4 + y 4 + 2 (x 4t) 2 y 2 + (x 4t) 2 z 2 + y 2 z 2 + (x + 2t) 2 (y 2 3 t) 2 + (x + 2t) 2 z 2 + (y 2 3 t) 2 z 2 + (x + 2t) 2 (y + 2 3 t) 2 + (x + 2t) 2 z 2 + (y + 2 3 t) 2 z 2 + (z 4 2 t) 2 x 2 + (z 4 2 t) 2 y 2 + x 2 y 2] = x 4 4x 3 4t + 6x 2 (4t) 2 4x(4t) 3 + (4t) 4 + y 4 + z 4 + 2 x 4 + 4x 3 (2t) + 6x 2 (2t) 2 + 4x(2t) 3 + (2t) 4 + z 4 4z 3 4 2 t + 6z 2 (4 2 t) 2 + y 4 + 6y 2 (2 3 t) 2 + (2 3 t) 4 + z 4] 4z(4 2 t) 3 + (4 2 t) 4 + x 4 + y 4 + 2 (x 4t) 2 (y 2 + z 2 ) + y 2 z 2 + (x + 2t) 2 2(y 2 + 12t 2 ) + 2z 2 (x + 2t) 2 + 2z 2 (y 2 + 12t 2 ) + (z 4 2 t) 2 (x 2 + y 2 ) + x 2 y 2] = x 4 + y 4 + z 4 16x 3 t + 96x 2 t 2 256xt 3 + 256t 4 + 2 x 4 + y 4 + z 4 + 8x 3 t + 24x 2 t 2 6

+ 32xt 3 + 16t 4 + 72x 2 t 2 + 144t 4] + x 4 + y 4 + z 4 16 2 z 3 t +192z 2 t 2 512 2 zt 3 1024t 4 + 2 x 2 y 2 + y 2 z 2 + (y 2 + z 2 )(x 2 + 16t 2 8xt) + (x 2 + y 2 ) ( z 2 8 2 zt + 32t 2) ( )] + 2 (y 2 +12t 2 )(x +2t) 2 + z 2 (x +2t) 2 + z 2 (y 2 +12t 2 ) = 4 x 4 + y 4 + z 4 + 36x 2 t 2 48xt 3 + 400t 4 + 36y 2 t 2 4 2 z 3 t + 48z 2 t 2 128 2 zt 3] + 2 2x 2 y 2 + 2y 2 z 2 + 2x 2 z 2 + 48y 2 t 2 8xty 2 + 16z 2 t 2 8xtz 2 8 2 ztx 2 + 32t 2 x 2 8 2 zty 2 ( + 2 y 2 x 2 + 4xty 2 + 4y 2 t 2 + z 2 x 2 + 4z 2 xt + 4z 2 t 2 + 12x 2 t 2 + 48xt 3 + 48t 4 + y 2 z 2 + 12z 2 t 2)] = = = 4 x 4 + y 4 + z 4 + 2x 2 y 2 + 2x 2 z 2 + 2y 2 z 2 + 64x 2 t 2 + 64y 2 t 2 + 72z 2 t 2 128 2 zt 3 + 448t 4 4 2 z 3 t 4 2 zx 2 t 4 ] 2 zy 2 t = 4 (x 2 + y 2 + ( z 2 t ) ) 2 2 + 60t 2( x 2 + y 2 + ( z 2 t ) 2 ) + 324t 4]. 7

In L and R notations: ( S (4) = 4 L 4 + R 4 + 10 3 L2 R 2). Theorem 2.1. The sum of the fourth power distances S (4), from an arbitrary point on any sphere with center at the centroid of a regular tetrahedron to the vertices of the tetrahedron, is constant S (4) = 4 (L 2 + R 2 ) 2 + 4 3 L2 R 2], (2) where L is the radius of the sphere and R is the circumradius of the tetrahedron. For given tetrahedron R is fixed and from the expression S (4) the equivalency follows: S (4) = const L = const, so is true vice versa: Theorem 2.2. The set of points, from which the sum of the fourth power distances S (4) to the vertices of a regular tetrahedron is constant, is: - the sphere with center at the centroid of the tetrahedron, if S (4) > 4R 4 ; - the point the centroid of the tetrahedron, if S (4) = 4R 4 ; - the empty set, if S (4) < 4R 4 ; where R is the circumradius of the tetrahedron. As for the sums of high powers (more than 4), they will no longer be constant. 8

3 Cube Introduce the Cartesian coordinate system with the origin at the centroid of the cube and with axes parallel to the sides of the cube. Denote the sides by 2a. Then the coordinates of the vertices are: P 1 (a, a, a), P 2 (a, a, a), P 3 (a, a, a), P 4 (a, a, a), P 5 ( a, a, a), P 6 ( a, a, a), P 7 ( a, a, a), P 8 ( a, a, a). The sphere equation with center at the centroid and any radius L: x 2 + y 2 + z 2 = L 2. The circumradius of the cube R = a 3. The square distances from an arbitrary X(x, y, z) point to the vertices are: d 2 (X, P 1 ) = (x a) 2 + (y + a) 2 + (z a) 2, d 2 (X, P 2 ) = (x a) 2 + (y + a) 2 + (z + a) 2, d 2 (X, P 3 ) = (x a) 2 + (y a) 2 + (z a) 2, d 2 (X, P 4 ) = (x a) 2 + (y a) 2 + (z + a) 2, d 2 (X, P 5 ) = (x + a) 2 + (y a) 2 + (z a) 2, d 2 (X, P 6 ) = (x + a) 2 + (y a) 2 + (z + a) 2, d 2 (X, P 7 ) = (x + a) 2 + (y + a) 2 + (z a) 2, 9

d 2 (X, P 8 ) = (x + a) 2 + (y + a) 2 + (z + a) 2. The sum of the square distances: S (2) = 8 d 2 (X, P i ) = 8 x 2 + y 2 + z 2 + 3a 2] = 8(L 2 + R 2 ) which is (1). The sum of the fourth power distances: S (4) = 8 d 4 (X, P i ) = 4 (x + a) 4 + (x a) 4 + (y + a) 4 + (y a) 4 + (z + a) 4 + (z a) 4] + 4 (x + a) 2 (y + a) 2 + (x + a) 2 (y a) 2 + (x + a) 2 (z + a) 2 + (x + a) 2 (z a) 2 + (x a) 2 (y + a) 2 + (x a) 2 (y a) 2 + (x a) 2 (z + a) 2 + (x a) 2 (z a) 2 + (y + a) 2 (z + a) 2 + (y + a) 2 (z a) 2 + (y a) 2 (z + a) 2 + (y a) 2 (z a) 2] = 8 x 4 + y 4 + z 4 + 6x 2 a 2 + 6y 2 a 2 + 6z 2 a 2 + 3a 4] + 4 2(x + a) 2 (y 2 + a 2 ) + 2(x + a) 2 (z 2 + a 2 ) 10

+ 2(x a) 2 (y 2 + a 2 ) + 2(x a) 2 (z 2 + a 2 ) ] + 2(y + a) 2 (z 2 + a 2 ) + 2(y a) 2 (z 2 + a 2 ) = 8 x 4 + y 4 + z 4 + 6x 2 a 2 + 6y 2 a 2 + 6z 2 a 2 + 3a 4 + (x + a) 2 (y 2 + z 2 + 2a 2 ) + (x a) 2 (y 2 + z 2 + 2a 2 ) ] + 2(z 2 + a 2 )(y 2 + a 2 ) = 8 x 4 + y 4 + z 4 + 6x 2 a 2 + 6y 2 a 2 + 6z 2 a 2 + 3a 4 ] + 2(y 2 + z 2 + 2a 2 )(x 2 + a 2 ) + 2(z 2 + a 2 )(y 2 + a 2 ) = 8 y 4 + y 4 + z 4 + 2x 2 y 2 + 2x 2 z 2 + 2z 2 y 2 + 10x 2 a 2 + 10y 2 a 2 + 10z 2 a 2 + 9a 4] = 8 (x 2 + y 2 + z 2 ) 2 + 10a 2 (x 2 + y 2 + z 2 ) + 9a 4] = 8 L 4 + R 4 + 10 3 L2 R 2]. Theorem 3.1. The sum of the fourth power distances S (4), from an arbitrary point on any sphere with center at the centroid of a cube to the vertices of the cube, is constant S (4) = 8 (L 2 + R 2 ) 2 + 4 3 L2 R 2], (3) where L is the radius of the sphere and R is the circumradius of the cube. From the equivalency 11

S (4) = const L = const, is true vice versa: Theorem 3.2. The set of points, from which the sum of the fourth power distances S (4) to the vertices of a cube is constant, is: - the sphere with center at the centroid of the cube, if S (4) > 8R 4 ; - the point the centroid of the cube, if S (4) = 8R 4 ; - the empty set, if S (4) < 8R 4 ; where R is the circumradius of the cube. Consider the sum of the sixth power distances: S (6) = 8 d 6 (X, P i ). To simplify this expression we use the following identity: (u + v + w) 3 = u 3 + v 3 + w 3 + 3(u + v)(u + w)(v + w). S (6) = (x + a) 6 + (y + a) 6 + (z + a) 6 ((x + 3 + a) 2 + (y + a) 2)( (x + a) 2 + (z + a) 2) ( (y + a) 2 + (z + a) 2)] + (x + a) 6 + (y + a) 6 + (z a) 6 12

((x + 3 + a) 2 + (y + a) 2)( (x + a) 2 + (z a) 2) ( (y + a) 2 + (z a) 2)] + (x + a) 6 + (y a) 6 + (z + a) 6 ((x + 3 + a) 2 + (y a) 2)( (x + a) 2 + (z + a) 2) ( (y a) 2 + (z + a) 2)] + (x + a) 6 + (y a) 6 + (z a) 6 ((x + 3 + a) 2 + (y a) 2)( (x + a) 2 + (z a) 2) ( (y a) 2 + (z a) 2)] + (x a) 6 + (y + a) 6 + (z + a) 6 ((x + 3 a) 2 + (y + a) 2)( (x a) 2 + (z + a) 2) ( (y + a) 2 + (z + a) 2)] + (x a) 6 + (y + a) 6 + (z a) 6 ((x + 3 a) 2 + (y + a) 2)( (x a) 2 + (z a) 2) ( (y + a) 2 + (z a) 2)] + (x a) 6 + (y a) 6 + (z + a) 6 ((x + 3 a) 2 + (y a) 2)( (x a) 2 + (z + a) 2) ( (y a) 2 + (z + a) 2)] 13

+ (x a) 6 + (y a) 6 + (z a) 6 ((x + 3 a) 2 + (y a) 2)( (x a) 2 + (z a) 2) ( (y a) 2 + (z a) 2)] = 4 (x + a) 6 + (x a) 6 + (y + a) 6 ((x + 3 + a) 2 + (y + a) 2) + (y a) 6 + (z + a) 6 + (z a) 6] ( ((x + a) 2 + (z + a) 2)( (y + a) 2 + (z + a) 2) + ( (x + a) 2 + (z a) 2)( (y + a) 2 + (z a) 2)) + ( (x + a) 2 + (y a) 2) ( ((x + a) 2 + (z + a) 2)( (y a) 2 + (z + a) 2) + ( (x + a) 2 + (z a) 2)( (y a) 2 + (z a) 2)) + ( (x a) 2 + (y + a) 2) ( ((x a) 2 + (z + a) 2)( (y + a) 2 + (z + a) 2) + ( (x a) 2 + (z a) 2)( (y + a) 2 + (z a) 2)) + ( (x a) 2 + (y a) 2) ( ((x a) 2 + (z + a) 2)( (y a) 2 + (z + a) 2) 14

+ ( (x a) 2 + (z a) 2)( (y a) 2 + (z a) 2))]. The second addend equals: ((x 3 + a) 2 + (y + a) 2)( (x + a) 2 (y + a) 2 + (x + a) 2 (z + a) 2 + (y + a) 2 (z + a) 2 + (z + a) 4 + (x + a) 2 (y + a) 2 + (x + a) 2 (z a) 2 + (y + a) 2 (z a) 2 + (z a) 4) + ( (x + a) 2 + (y a) 2)( (x + a) 2 (y a) 2 + (x + a) 2 (z + a) 2 + (y a) 2 (z + a) 2 + (z + a) 4 + (x + a) 2 (y a) 2 + (x + a) 2 (z a) 2 + (y a) 2 (z a) 2 + (z a) 4) + ( (x a) 2 + (y + a) 2)( (x a) 2 (y + a) 2 + (x a) 2 (z + a) 2 + (y + a) 2 (z + a) 2 + (z + a) 4 + (x a) 2 (y + a) 2 + (x a) 2 (z a) 2 + (y + a) 2 (z a) 2 + (z a) 4) + ( (x a) 2 + (y a) 2)( (x a) 2 (y a) 2 + (x a) 2 (z + a) 2 + (y a) 2 (z + a) 2 + (z + a) 4 + (x a) 2 (y a) 2 + (x a) 2 (z a) 2 + (y a) 2 (z a) 2 + (z a) 4)] ((x = 3 + a) 2 + (y + a) 2) ( 2(x + a) 2 (y + a) 2 + 2(x + a) 2 (z 2 + a 2 ) 15

+ 2(y + a) 2 (z 2 + a 2 ) + ( (z a) 4 + (z + a) 4)) + ( (x + a) 2 + (y a) 2) ( 2(x + a) 2 (y a) 2 + 2(x + a) 2 (z 2 + a 2 ) + 2(y a) 2 (z 2 + a 2 ) + ( (z + a) 4 + (z a) 4)) + ( (x a) 2 + (y + a) 2) ( 2(x a) 2 (y + a) 2 + 2(x a) 2 (z 2 + a 2 ) + 2(y + a) 2 (z 2 + a 2 ) + ( (z + a) 4 + (z a) 4)) + ( (x a) 2 + (y a) 2) ( 2(x a) 2 (y a) 2 + 2(x a) 2 (z 2 + a 2 ) + 2(y a) 2 (z 2 + a 2 ) + ( (z + a) 4 + (z a) 4)). By using (z + a) 4 + (z a) 4 = (z 2 + a 2 + 2az) 2 + (z 2 + a 2 2az) 2 = ( (z 2 + a 2 ) 2 + 4a 2 z 2) 2 the second addend is: 6 2(x + a) 4 (y 2 + a 2 ) + 2(x + a) 4 (z 2 + a 2 ) + 2(x + a) 2 (y 2 + a 2 )(z 2 + a 2 ) + 2(z 2 + a 2 ) 2 (x + a) 2 16

+ 4a 2 z 2 (x + a) 2 + (x + a) 2( (y + a) 4 + (y a) 4) + 2(x+a) 2 (y 2 +a 2 )(z 2 +a 2 ) + (z 2 +a 2 ) ( (y+a) 4 + (y a) 4) + 2(y 2 + a 2 )(z 2 + a 2 ) 2 + 8a 2 z 2 (y 2 + a 2 ) +2(x a) 4 (y 2 + a 2 ) + 2(z 2 + a 2 )(x a) 4 + 2(x a) 2 (y 2 + a 2 )(z 2 + a 2 ) + 2(x a) 2 (z 2 + a 2 ) 2 + 4a 2 z 2 (x a) 2 + (x a) 2( (y + a) 4 + (y a) 4) + 2(x a) 2 (y 2 +a 2 )(z 2 +a 2 ) + (z 2 +a 2 ) ( (y+a) 4 + (y a) 4) ] + 2(y 2 + a 2 )(z 2 + a 2 ) 2 + 8a 2 z 2 (y 2 + a 2 ) = 6 2(y 2 + a 2 ) ( (x + a) 4 + (x a) 4) + 2(z 2 + a 2 ) ( (x + a) 4 (x a) 4) + 4(x 2 + a 2 )(y 2 + a 2 )(z 2 + a 2 ) + 4(x 2 + a 2 )(z 2 + a 2 ) 2 + 8a 2 z 2 (x 2 + a 2 ) + 2 2(x 2 + a 2 )(y 2 + a 2 ) 2 + 16a 2 y 2 (x 2 + a 2 ) + 4(x 2 + a 2 )(y 2 + a 2 )(z 2 + a 2 ) + 2 2(z 2 + a 2 ) ( (y 2 + a 2 ) 2 + 4a 2 y 2 ) ] + 4(y 2 + a 2 )(z 2 + a 2 ) 2 + 16a 2 z 2 (y 2 + a 2 ) = 12 2(y 2 + a 2 )(x 2 + a 2 ) 2 + 8(y 2 + a 2 )a 2 x 2 + 2(z 2 + a 2 )(x 2 + a 2 ) 2 + 8a 2 x 2 (z 2 + a 2 ) + 4(x 2 + a 2 )(y 2 + a 2 )(z 2 + a 2 ) 17

+ 2(x 2 + a 2 )(z 2 + a 2 ) 2 + 8a 2 z 2 (x 2 + a 2 ) + 2(x 2 + a 2 )(y 2 + a 2 ) 2 + 8a 2 y 2 (x 2 + a 2 ) + 2(z 2 + a 2 )(y 2 + a 2 ) 2 + 8a 2 y 2 (z 2 + a 2 ) ] + 2(y 2 + a 2 )(z 2 + a 2 ) 2 + 8a 2 z 2 (y 2 + a 2 ) ( S (6) = 24 14a 2 (x 2 y 2 + x 2 z 2 + y 2 z 2 ) + 16a 4 (x 2 + y 2 + z 2 ) + 2a 2 (x 4 + y 4 + z 4 ) + (y 2 x 4 +z 2 x 4 +x 2 z 4 +x 2 y 4 +z 2 y 4 +y 2 z 4 )+8a 6 +2x 2 y 2 z 2) ( + 8 x 6 + y 6 + z 6 + 15a 2 (x 4 + y 4 + z 4 ) + 15a 4 (x 2 + y 2 + z 2 ) + 3a 6) = 24(y 2 x 4 + z 2 x 4 + x 2 z 4 + x 2 y 4 + z 2 y 4 + y 2 z 4 ) + (24 16 + 8 15)a 4 (x 2 + y 2 + z 2 ) + (24 2 + 8 15)a 2 (x 4 + y 4 + z 4 ) + 8(x 6 + y 6 + z 6 ) + 48x 2 y 2 z 2 + (24 8 + 24)a 6 = 8(x 6 +y 6 +z 6 )+24(y 2 x 4 +x 4 z 2 +z 4 x 2 +x 2 y 4 +y 4 z 2 +y 2 z 4 ) + 48x 2 y 2 z 2 + 168a 2 (x 4 + y 4 + z 4 ) + 336a 2 (x 2 y 2 +x 2 z 2 +y 2 z 2 )+504a 4 (x 2 +y 2 +z 2 )+216a 6. Now get back to L and R notations: 18

S (6) = 8L 6 + 168a 2 L 4 + 504a 4 L 2 + 216a 6 = 8 L 6 + 7R 2 L 4 + 7R 4 L 2 + R 6] = 8(L 2 + R 2 )(L 4 + R 4 + 6L 2 R 2 ). Theorem 3.3. The sum of the sixth power distances S (6), from an arbitrary point on any sphere with center at the centroid of a cube to the vertices of the cube, is constant ] S (6) = 8 (L 2 + R 2 ) 3 + 4L 2 R 2 (L 2 + R 2 ), (4) where L is the radius of the sphere and R is the circumradius of the cube. From the equivalency S (6) = const L = const is true vice versa: Theorem 3.4. The set of points, from which the sum of the sixth power distances S (6) to the vertices of a cube is constant, is: - the sphere with center at the centroid of the cube, if S (6) > 8R 6 ; - the point the centroid of the cube, if S (6) = 8R 6 ; - the empty set, if S (6) < 8R 6 ; where R is the circumradius of the cube. As for the sums of high powers (more than 6), they will no longer be constant. 19

4 Summary Summarize (1) and obtained (2) (4) results. Consider a regular tetrahedron and a cube. Denote the cercumradius by R and the centroid by O, respectively. If an arbitrary point X moves on any sphere with center at O and the radius L, the sums S (2m) of power distances d 2m (X, P i ) from this point to the vertices P i are constant for the following powers and equal: Regular Tetrahedron: S (2) = S (4) = 4 d 2 (X, P i ) = 4(L 2 + R 2 ), 4 d 4 (X, P i ) = 4 (L 2 + R 2 ) 2 + 4 3 L2 R 2]. Cube: S (2) = S (4) = S (6) = 8 d 2 (X, P i ) = 8(L 2 + R 2 ), 8 8 d 4 (X, P i ) = 8 (L 2 + R 2 ) 2 + 4 3 L2 R 2], ] d 6 (X, P i ) = 8 (L 2 + R 2 ) 3 + 4L 2 R 2 (L 2 + R 2 ). We have perfectly investigated two of Platonic solids the regular tetrahedron and the cube. Consideration of other Platonic solids the octahedron (n = 6), the icosahedron (n = 12) and the dodecahedron (n = 20) is the aim of the future studies. 20

References 1] J. Steiner, Gesammelte Werke. Herausgegeben von K. Weierstrass. Bd. II. (German) G. Reimer, Berlin, (1881,1882). 2] T. M. Apostol, M. A. Mnatsakanian, Sums of squares of distances in m-space. Amer. Math. Monthly 110 (2003), no. 6, 516 526. 3] M. Meskhishvili, New sense of a circle. arxiv:1905.10406math.gm], 2019; https://arxiv.org/abs/1905.10406. Author s address: Georgian-American High School, 18 Chkondideli Str., Tbilisi 0180, Georgia. E-mail: mathmamuka@gmail.com 21

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback