mathematical analysis of truncated icosahedron & identical football by applying hcr's...

Mathematical analysis of truncated icosahedron & football Application of HCR’s formula for regular polyhedrons (all five platonic solids)

Applications of “HCR’s Theory of Polygon” proposed by Mr H.C. Rajpoot (year-2014) ©All rights reserved

Mr Harish Chandra Rajpoot

M.M.M. University of Technology, Gorakhpur-273010 (UP), India Dec, 2014

Introduction: A truncated icosahedron is a solid which has 12 congruent regular pentagonal & 20 congruent

regular hexagonal faces each having equal edge length. It is obtained by truncating a regular icosahedron

(having 20 congruent faces each as an equilateral triangle) at the vertices to generate 12 regular pentagonal &

20 regular hexagonal faces of equal edge length. For calculating all the parameters of a truncated icosahedron,

we would use the equations of right pyramid & regular icosahedron. When a regular icosahedron is truncated

at the vertex, a right pyramid with base as a regular pentagon & certain normal height is obtained. Since, a

regular icosahedron has 12 vertices hence we obtain 12 truncated off congruent right pyramids each with a

regular pentagonal base.

Truncation of a regular icosahedron: For ease of calculations, let there be a regular icosahedron with edge

length & its centre at the point C. Now it is truncated at all 12 vertices to obtain a truncated icosahedron.

Thus each of the congruent equilateral triangular faces with edge length is changed into a regular

hexagonal face with edge length (see figure 2) & we obtain 12 truncated off congruent right pyramids with

base as a regular pentagon corresponding to 12 vertices of the parent solid. (See figure 1 showing a right

pyramid with regular pentagonal base & normal height being truncated from the regular icosahedron).

Figure 1: A right pyramid with base as a regular pentagon with side length 𝒂 & normal height h is truncated off from a regular icosahedron with edge length 𝟑𝒂

Figure 2: Each of the congruent equilateral triangular faces with edge length 𝟑𝒂 of a regular icosahedron is changed into a regular hexagonal face with edge length 𝒂 by truncation of vertices.



Analysis of Truncated icosahedron by using equations of right pyramid & regular icosahedron

Now consider any of 12 truncated off congruent right pyramids having base as a regular pentagon ABDEF with

side length , normal height & an angle between any two consecutive lateral edges (see figure 3 below)

Normal height ( ) of truncated off right pyramid: We know that the normal height of any right pyramid

is given as

√

√

√(√ )

(

√

√ √ )

Figure 3: Normal distance ( ) of regular pentagonal faces is always greater than the normal distance ( ) of regular

hexagonal faces measured from the centre C of any truncated icosahedron.

⇒

√

√ √

√

√

( √ )

√ √

(√ )

√

(√ )

√ √

(√ )

√ √

(√ )

( )



Volume ( ) of truncated off right pyramid: We know that the volume of a right pyramid is given as

( ) ( )

(

)

(

)

(√ )

√ √

(

√

√ √ )

(√ )

√ √

(

√ )

( √ )

( √ )( √ )

( √ )

( √ )

( )

Normal distance ( ) of regular pentagonal faces from the centre of truncated icosahedron: The

normal distance ( ) of each of the regular pentagonal faces from the centre C of truncated icosahedron is

given as

( )

⇒ ( ( ) )

⇒ ( ) (√ )

√ √ ( )

√ √

(√ )

√ √

(

√( √ )( √ ) (√ )

√ √ )

( √ √

√ √ )

⇒ ( √

√ √ )

( √ )

√ √

( √ )

( )

It’s clear that all 12 congruent regular pentagonal faces are at an equal normal distance from the centre

of any truncated icosahedron.

Solid angle ( ) subtended by each of the regular pentagonal faces at the centre of truncated

icosahedron: we know that the solid angle ( ) subtended by any regular polygon with each side of length

at any point lying at a distance H on the vertical axis passing through the centre of plane is given by “HCR’s

Theory of Polygon” as follows

(

√ )

Hence, by substituting the corresponding values in the above expression, we get



(

(

( √ )

√ √ )

√ ( ( √ )

√ √ )

)

(

( √ )

√ √

√ √

√ ( √ )

√ (

√

√ √ )

)

(

( √ )√ √

√ √ √

)

(( √ )√ √

√ √ ) (

( √ )√ √

√ √ )

(( √ )√ √ √ √

√ √ √ √ ) (

( √ ) √

( √ ))

( ( √ )

( √ )) (

( √ )( √ )

( √ )( √ ))

( ( √ √ )

( )) (

( √ )

( ))

( √

) ( )

Normal distance ( ) of regular hexagonal faces from the centre of truncated icosahedron: The

normal distance ( ) of each of the regular hexagonal faces from the centre C of truncated icosahedron is

given as

( )

⇒ ( ( ) )

⇒ ( √ )( )

√ ( )

⇒ √ ( √ )

( )

It’s clear that all 20 congruent regular hexagonal faces are at an equal normal distance from the centre of

any truncated icosahedron.

It’s also clear from eq(III) & (V) i.e. the normal distance ( ) of regular pentagonal faces is greater

than the normal distance ( ) of regular hexagonal faces from the centre of truncated icosahedron i.e.

hexagonal faces are much closer to the centre as compared to the pentagonal faces in any truncated

icosahedron.



Solid angle ( ) subtended by each of the regular hexagonal faces at the centre of truncated

icosahedron: we know that the solid angle ( ) subtended by any regular polygon is given by “HCR’s Theory

of Polygon” as follows

(

√ )

Hence, by substituting the corresponding values in the above expression, we get

(

(

√ ( √ )

)

√ (√ ( √ )

)

)

(

(

√ ( √ )

)

√ ( √ )

(√ )

)

(√ ( √ )

√ √ )

(

√ ( √ )

√ ( √ ))

(√ √ √

√ ) (

√

√

)

(

√

√

)

(

√(√ )

√ )

(√

√ )

(√

√ ) (

√ ) ( )

It’s clear that the solid angle subtended by each of the regular hexagonal faces is greater than the solid angle

subtended by each of the regular pentagonal faces at the centre of any truncated icosahedron.

Important parameters or dimensions of a truncated icosahedron:

1. Inner (inscribed) radius( ): It is the radius of the largest sphere inscribed (trapped inside) by a

truncated icosahedron. The largest inscribed sphere always touches all 20 congruent regular

hexagonal faces but does not touch any of 12 regular pentagonal faces at all since all 20 hexagonal

faces are closer to the centre as compared to all 12 pentagonal faces. Thus, inner radius is always

equal to the normal distance ( ) of hexagonal faces from the centre & is given from the eq(V) as

follows

√ ( √ )

Hence, the volume of inscribed sphere is given as



( )

(

√ ( √ )

)

2. Outer (circumscribed) radius( ): It is the radius of the smallest sphere circumscribing a given

truncated icosahedron or it’s the radius of a spherical surface passing through all 60 vertices of a

given truncated icosahedron. It is calculated as follows (See figure 3 above).

In right

⇒

( )

(

)

In right

⇒ √( ) ( ) √(

)

( ( √ )

)

( )

√

√

√ √

√ √ √

( √ )( √ )

( √ )( √ ) √

√

√ √

√ √

( )

Hence, outer radius of truncated icosahedron is given as

√ √

Hence, the volume of circumscribed sphere is given as

( )

(

√ √

)

3. Surface area( ): We know that a truncated icosahedron has 12 congruent regular pentagonal & 20

regular hexagonal faces each of edge length . Hence, its surface area is given as follows

( ) ( )

We know that area of any regular n-polygon with each side of length is given as

Hence, by substituting all the corresponding values in the above expression, we get

(

) (

) √

( √ )



4. Volume( ): We know that a truncated icosahedron with edge length is obtained by truncating a

regular icosahedron with edge length at all its 12 vertices. Thus, 12 congruent right pyramids with

regular pentagonal base are truncated off from a parent regular icosahedron. Hence, the volume (V)

of the truncated icosahedron is given as follows

( ) ( )

(

( √ )( ) ) ( ) ( )

(

( √ ) ) (

( √ )

) ( ( ))

( √ )

( √ )

( √ √ )

( √ )

( √ )

5. Mean radius( ): It is the radius of the sphere having a volume equal to that of a given truncated

icosahedron. It is calculated as follows

( )

( √ )

⇒ ( )

( √ )

( ( √ )

)

It’s clear from above results that

Construction of a solid truncated icosahedron: In order to construct a solid truncated icosahedron with

edge length there are two methods

1. Construction from elementary right pyramids: In this method, first we construct all elementary right

pyramids as follows

Construct 12 congruent right pyramids with regular pentagonal base of side length & normal height ( )

( √ )

Construct 20 congruent right pyramids with regular hexagonal base of side length & normal height ( )

√ ( √ )

Now, paste/bond by joining all these right pyramids by overlapping their lateral surfaces & keeping their apex

points coincident with each other such that all edges of each pentagonal base (face) coincide with the edges of

five hexagonal bases (faces). Thus, a solid truncated icosahedron with 12 congruent regular pentagonal & 20

congruent regular hexagonal faces each of edge length is obtained.



2. Machining a solid sphere: It is a method of machining, first we select a blank as a solid sphere of certain

material (i.e. metal, alloy, composite material etc.) & with suitable diameter in order to obtain the maximum

desired edge length of truncated icosahedron. Then, we perform facing operation on the solid sphere to

generate 12 congruent regular pentagonal & 20 congruent regular hexagonal faces each of equal edge length.

Let there be a blank as a solid sphere with a diameter D. Then the edge length , of a truncated icosahedron of

maximum volume to be produced, can be co-related with the diameter D by relation of outer radius ( ) with

edge length ( )of a truncated icosahedron as follows

√ √

Now, substituting ⁄ in the above expression, we have

√ √

√ √

Above relation is very useful for determining the edge length of a truncated icosahedron to be produced

from a solid sphere with known diameter D for manufacturing purposes.

Hence, the maximum volume of truncated icosahedron produced from the solid sphere is given as follows

( √ )

( √ )

(

√ √ )

( √ )

( √ )√ √

( √ )( √ )

( √ )( √ )√ √

( √ )

√ √

( √ )

√ √

Minimum volume of material removed is given as

( ) ( ) ( )

( √ )

√ √ (

( √ )

√ √ )

( ) (

( √ )

√ √ )

Percentage ( ) of minimum volume of material removed



(

( √ )

√ √ )

(

( √ )

√ √ )

It’s obvious that when a truncated icosahedron of maximum volume is produced from a solid sphere then

about of material is removed as scraps. Thus, we can select optimum diameter of blank as a solid

sphere to produce a truncated icosahedron of maximum volume (or with maximum desired edge length)

Analysis of Football: let there be a football with a diameter D (outside) having 12 congruent regular

spherical pentagons & 20 congruent regular spherical hexagons on its surface. This case of the football is

similar to the case of a truncated icosahedron. The only difference is that a football has spherical faces instead

of flat faces of a truncated icosahedron. But in both the cases, the values of solid angle subtended by each of

regular pentagonal & each of regular hexagonal faces are constant & are independent of the geometrical

dimensions (i.e. diameter & edge length) of both the football & the truncated icosahedron. Hence, we have

the following important parameters of a football with a certain diameter (outside)

1. Solid angle subtended by each of 12 congruent regular spherical pentagons is given as

( √

)

2. Area of each of 12 congruent regular spherical pentagons is given as

( ) ( )

(

)

( (

√

))

(

(

√

))

3. Solid angle subtended by each of 20 congruent regular spherical hexagons is given as

(

√ )

4. Area of each of 20 congruent regular spherical hexagons is given as

( ) ( )

(

)

( (

√ ))

(

(

√ ))

It’s clear from the above results that the solid angle subtended by each of 12 congruent regular spherical

pentagons is smaller than the solid angle subtended by each of 20 congruent regular spherical hexagons at

the centre of the football & hence the area of a regular spherical pentagon is smaller than that of a regular

spherical hexagon. Solid angle subtended by any of the faces of football is independent of the diameter.



Conclusions: let there be any truncated icosahedron having 12 congruent regular pentagonal & 20

congruent regular hexagonal faces each with edge length then all its important parameters are

calculated/determined as tabulated below

Congruent polygonal faces

No. of faces

Normal distance of each face from the centre of the given truncated icosahedron

Solid angle subtended by each face at the centre of the given truncated icosahedron

Regular pentagon

12

( √ )

( √

)

Regular hexagon

20

√ ( √ )

(

√ )

Inner (inscribed) radius ( )

√ ( √ )

Outer (circumscribed) radius ( )

√ √

Mean radius ( )

( ( √ )

)

Surface area ( )

( √ )

Volume ( )

( √ )

Note: Above articles had been developed & illustrated by Mr H.C. Rajpoot (B Tech, Mechanical Engineering)

M.M.M. University of Technology, Gorakhpur-273010 (UP) India Dec, 2014

Email: [email protected]

Author’s Home Page: https://notionpress.com/author/HarishChandraRajpoot

Courtesy: Advanced Geometry by Harish Chandra Rajpoot

mailto:[email protected]

https://notionpress.com/author/HarishChandraRajpoot

mathematical analysis of truncated icosahedron & identical football by applying hcr's...

Engineering

regular polyhedrons

regular pentagon abdef

edge length figure

congruent right pyramids

congruent faces

length normal height

rajpoot year

truncation of vertices