Fractal Geometry, Tessellations and Symmetry Lesson 3 PDF

Summary

This document provides a lesson on fractal geometry, tessellations, and symmetry, explaining concepts like self-similarity and examples in nature. It introduces the topic through several examples and diagrams.

Full Transcript

Fractal Geometry, Tessellations and
Symmetry
Lesson 3

GED0103 Math in the Modern World
Institute of Arts and Sciences
FAR EASTERN UNIVERSITY
What is Fractal Geometry?
What are fractals?
Mathematical constructs characterized by self-similarity.
Geometric patterns that is repeated at ever smaller scales to produce irregular
shapes and surfaces that can not be represented by classical geometry.
Came from the Latin adjective “fractus” or verb “frangere” which means to break.
named and popularized by mathematician Benoit Mandelbrot (1924 – 2010).
In 1977, Mandelbrot wrote The Fractal Geometry of Nature, and he stated:
“Clouds are not spheres, mountains are not cones, coastlines are not circles, and
bark is not smooth, nor does lightning travel is a straight line.”
Some popular fractals are: Sierpinski triangle, Pascal’s triangle, Koch snowflake,
fractal trees and Barnsley ferns
What are fractals?
Purely a wonder phenomenon,
They are everywhere
▪ They are present in food, germs, plants, animals, mountains, forests,
water and in the sky.
They are repetitive, circular, looping recurrent, recursive,
iterative and infinite
a rough or fragmented geometric shape that can be split into
parts, each of which is (at least approximately) a reduced-size
copy of the whole, a property called self-similarity
Fractals found in nature
 Fractals found in nature Romanesco
brocolli

brocolli
Fractals found in nature Queen
Anne’s
Lace

Ferns
Fractals found in nature

clouds Mountain ranges
Fractals found in nature
Fractals found in nature
Fractals found in nature
FEATURES Common Techniques for Generating
Fractals

It has a fine structure at Escape-Time
arbitrarily small scales. Iterated Function Systems
It is too irregular to be easily Random
described in traditional
Euclidean geometric language. Recursive
It is self-similar (at least
approximately or stochastically).
It has a simple and recursive
definition.
Example 1: Sierpinski Fractals
Sierpinski triangle, is a fractal and attractive fixed set with the overall shape of an
equilateral triangle, subdivided recursively into smaller equilateral triangles.
Named after Polish mathematician Waclaw Sierpinski, but appeared as a
decorative pattern many centuries prior to his work.
The Sierpinski triangle can be constructed as follows:
1. Start with an equilateral triangle (actual size does not matter)
2. Find the midpoint of each side.
3. Connect the midpoints by a straight line.
4. Observe that you created three more triangles one on top and two at the
bottom.
5. Repeat the process with all other triangles.
Example 1: Sierpinski Fractals

0 1 2 3 4
Iteration Math Notation Number of Triangles
(No of times you have
drawn a triangle)
0 30 1

1 31 3

2 32 9

3 33 27

4 34 81
Example 1: Sierpinski Fractals
has appeared many centuries earlier in artwork, patterns and mosaics.
here are some examples of floor tilings from different churches in Rome:
Pascal’s Triangle
a triangular array of the binomial
coefficients that arises in
probability theory, combinatorics,
and algebra.
a number pyramid in which every
number is the sum of the two
numbers above.
named after the French
mathematician Blaise Pascal,
although other mathematicians
studied it centuries before him in
India, Persia, China, Germany,
and Italy.
The rows of Pascal's triangle are
conventionally enumerated
starting with row n=0 at the top
(the 0th row).
Other Fractal shapes
What is Tessellations?
A tessellation is a special type of tiling (a pattern of geometric shapes that
fill a two-dimensional space with no gaps and no overlaps) that repeats
forever in all directions.
From the word “tessera” in Latin that means a small stone cube. They
were used to make up 'tessellata' - the mosaic pictures forming floors and
tilings in Roman buildings.
The term has become more specialized and is often used to refer to
pictures or tiles, mostly in the form of animals and other life forms, which
cover the surface of a plane in a symmetrical way without overlapping or
leaving gaps.
Tessellations figure prominently throughout art and architecture from
various time periods throughout history, from the intricate mosaics of
Ancient Rome, to the contemporary designs of M.C. Escher.
What is Tessellations?
While any polygon (a two-dimensional shape with any number of
straight sides) can be part of a tessellation, not every polygon can
tessellate by themselves
In a tessellation, whenever two or more polygons meet at a point
(or vertex), the internal angles must add up to 360°.
Only three regular polygons(shapes with all sides and angles equal)
can form a tessellation by themselves—triangles, squares,
and hexagons.

Examples:
What is Tessellations?
What about circles?
Circles are a type of oval—a convex, curved shape with no corners.
Circles can only tile the plane if the inward curves balance the outward
curves, filling in all the gaps.
While they can't tessellate on their own, they can be part of a
tessellation, but only if you view the triangular gaps between the circles
as shapes.
Types of Tessellations
Regular tessellations are composed of
identically sized and shaped regular
polygons.
Semi-regular tessellations are made from
multiple regular polygons. Only eight
combinations of regular polygons create
semi-regular tessellations.
Meanwhile, irregular tessellations (or
demiregular or polymorph tessellations)
consist of figures that aren't composed of
regular polygons that interlock without
gaps or overlaps. As you can probably
guess, there are an infinite number of
figures that form irregular tessellations!
Types of Tessellations
Regular tessellations are composed of
identically sized and shaped regular
polygons.
Semi-regular tessellations are made from
multiple regular polygons. Only eight
combinations of regular polygons create
semi-regular tessellations.
Meanwhile, irregular tessellations (or
demiregular or polymorph tessellations)
consist of figures that aren't composed of
regular polygons that interlock without
gaps or overlaps. As you can probably
guess, there are an infinite number of
figures that form irregular tessellations!
Look at a vertex
A vertex is just a "corner point".

What shapes meet here?
Three hexagons meet at this vertex,
and a hexagon has 6 sides.

So this is called a "6.6.6" tessellation.

For a regular tessellation, the pattern is identical at each vertex!
Regular Tesselations
Triangles
The interior angle of each equilateral triangle is 60 degrees.
60 + 60 + 60 + 60 + 60 + 60 = 360 degrees
Squares
The interior angle of each square is 90 degrees.
90 + 90 + 90 + 90 = 360 degrees
Hexagons
The interior angle of each Hexagon is 90 degrees.
120 + 120 + 120 = 360 degrees
What is Symmetry?
Symmetry is a concept that states that when we move one shape, such as
turning, flipping, or sliding it, it becomes identical to the other.
The word “Symmetry” comes from the Greek word which implies “to
measure together”.
When two or more parts are identical after a flip, slide or turn.
The two objects are claimed to be symmetrical, if they have the identical
size and shape with one object having a different orientation from the first.
Some great examples of symmetry in nature are starfish, peacocks, turtles,
sunflowers, honeycombs, snowflakes, rainbows, etc.
Types of Symmetry
1. Translational Symmetry
2. Rotational Symmetry
3. Reflectional Symmetry
4. Glide Reflection Symmetry
Types of Symmetry: Translational Symmetry
Translational symmetry is where a figure or an
image is translated at a set distance in the same
direction as the original. (moving or sliding)
The spaces between points, angles, sizes, and
shapes of the figure will not change. The only
thing that changes is its location.
You may move it right or left. You may move it up
or down. You may move it through a combination
of these two, but these are the only possibilities.
Types of Symmetry: Rotational Symmetry
also known as radial symmetry, is where a
shape or an image looks precisely similar to
the orotational symmetry by original form or
image after some rotation. (rotating or
turning)
We count the number of turns it takes, also
referred to as order, for a shape to look the
same. For example, a rectangle has an order of
2, and a five-point star has an order of 5.
You can find rotational symmetry naturally in
sea stars, jellyfish, and sea anemones. It also
appears in human-made objects like airplane
propellers, Ferris wheels, dartboards!
Types of Symmetry: Reflectional Symmetry
also known as reflexive, or mirror symmetry, refers to a shape that can be
reflected over a line and still resemble its original shape.
This is perhaps the most intuitively understood type of symmetry, observed
when one half of a figure is a mirror image of the other half. A classic example
is a heart shape or the wings of a butterfly.
The line which a reflection takes place over is known as the line of symmetry.
It’s also important to note that some shapes can
have multiple lines of symmetry. Take a square,
for example - you can draw four lines of
symmetry on a square—one horizontally across
the middle, one vertically down the middle, and
two going diagonally each way.
Types of Symmetry: Glide Reflection
Symmetry
best thought of as a hybrid between reflection and translational symmetry. It is a
type of symmetry where the figure or image looks precisely the original when it is
reflected over a line and then translated at a given distance in a given direction.
The footprints trail is one of the best examples of Glide Reflection Symmetry.
This type of symmetry involves both processes but in a specific order; reflection
over a line and translation along the line. A shape must first be reflected and then
translated in any direction for glide reflection to have taken place.
As in translational symmetry, glide-reflectional symmetry exists only for infinite
patterns.
Line of Symmetry
The line of symmetry is an imaginary line or
axis that passes through the center of any
picture, shape or object and it is divided into
two identical halves.

English Alphabets with vertical line of symmetry:
A, H, I, M, O, T, U, V, W, X, Y.

English Alphabets with horizontal line of symmetry:
B, C, D, E, H, I, K, O, X

English Alphabets with no line of symmetry:
F, G, J, L, N, P, Q, R, S, Z.