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Title: A Mathematical View of Our World


1
A Mathematical View of Our World
  • 1st ed.
  • Parks, Musser, Trimpe, Maurer, and Maurer

2
Chapter 2
  • Shapes in Our Lives

3
Section 2.1Tilings
  • Goals
  • Study polygons
  • Vertex angles
  • Regular tilings
  • Semiregular tilings
  • Miscellaneous tilings
  • Study the Pythagorean theorem

4
2.1 Initial Problem
  • A portion of a ceramic tile wall composed of two
    differently shaped tiles is shown. Why do these
    two types of tiles fit together without gaps or
    overlaps?
  • The solution will be given at the end of the
    section.

5
Tilings
  • Geometric patterns of tiles have been used for
    thousands of years all around the world.
  • Tilings, also called tessellations, usually
    involve geometric shapes called polygons.

6
Polygons
  • A polygon is a plane figure consisting of line
    segments that can be traced so that the starting
    and ending points are the same and the path never
    crosses itself.

7
Question
  • Choose the figure below that is NOT a polygon.
  • a. c.
  • b. d. all are polygons

8
Polygons, contd
  • The line segments forming a polygon are called
    its sides.
  • The endpoints of the sides are called its
    vertices.
  • The singular of vertices is vertex.

9
Polygons, contd
  • A polygon with n sides and n vertices is called
    an n-gon.
  • For small values of n, more familiar names are
    used.

10
Polygonal Regions
  • A polygonal region is a polygon together with the
    portion of the plan enclosed by the polygon.

11
Polygonal Regions, contd
  • A tiling is a special collection of polygonal
    regions.
  • An example of a tiling, made up of rectangles, is
    shown below.

12
Polygonal Regions, contd
  • Polygonal regions form a tiling if
  • The entire plane is covered without gaps.
  • No two polygonal regions overlap.

13
Polygonal Regions, contd
  • Examples of tilings with polygonal regions are
    shown below.

14
Vertex Angles
  • A tiling of triangles illustrates the fact that
    the sum of the measures of the angles in a
    triangle is 180.

15
Vertex Angles, contd
  • The angles in a polygon are called its vertex
    angles.
  • The symbol ? indicates an angle.
  • Line segments that join nonadjacent vertices in a
    polygon are called diagonals of the polygon.

16
Example 1
  • The vertex angles in the pentagon are called ? V,
    ?W, ?X, ?Y, and ?Z.
  • Two diagonals shown are WZ and WY.

17
Vertex Angles, contd
  • Any polygon can be divided, using diagonals, into
    triangles.
  • A polygon with n sides can be divided into n 2
    triangles.

18
Vertex Angles, contd
  • The sum of the measures of the vertex angles in a
    polygon with n sides is equal to

19
Example 2
  • Find the sum of measures of the vertex angles of
    a hexagon.
  • Solution
  • A hexagon has 6 sides, so n 6.
  • The sum of the measures of the angles is found to
    be

20
Regular Polygons
  • Regular polygons are polygons in which
  • All sides have the same length.
  • All vertex angles have the same measure.
  • Polygons that are not regular are called
    irregular polygons.

21
Regular Polygons, contd
22
Regular Polygons, contd
  • A regular n-gon has n angles.
  • All vertex angles have the same measure.
  • The measure of each vertex angle must be

23
Example 3
  • Find the measure of any vertex angle in a regular
    hexagon.
  • Solution
  • A hexagon has 6 sides, so n 6.
  • Each vertex angle in the regular hexagon has the
    measure

24
Vertex Angles, contd
25
Regular Tilings
  • A regular tiling is a tiling composed of regular
    polygonal regions in which all the polygons are
    the same shape and size.
  • Tilings can be edge-to-edge, meaning the
    polygonal regions have entire sides in common.
  • Tilings can be not edge-to-edge, meaning the
    polygonal regions do not have entire sides in
    common.

26
Regular Tilings, contd
  • Examples of edge-to-edge regular tilings.

27
Regular Tilings, contd
  • Example of a regular tiling that is not
    edge-to-edge.

28
Regular Tilings, contd
  • Only regular edge-to-edge tilings are generally
    called regular tilings.
  • In every such tiling the vertex angles of the
    tiles meet at a point.

29
Regular Tilings, contd
  • What regular polygons will form tilings of the
    plane?
  • Whether or not a tiling is formed depends on the
    measure of the vertex angles.
  • The vertex angles that meet at a point must add
    up to exactly 360 so that no gap is left and no
    overlap occurs.

30
Example 4
  • Equilateral Triangles (Regular 3-gons)
  • In a tiling of equilateral triangles, there are
    6(60) 360 at each vertex point.

31
Example 5
  • Squares
  • (Regular 4-gons)
  • In a tiling of squares, there are 4(90) 360
    at each vertex point.

32
Question
  • Will a regular pentagon tile the plane?
  • a. yes
  • b. no

33
Example 6
  • Regular hexagons
  • (Regular 6-gons)
  • In a tiling of regular hexagons, there are
    3(120) 360 at each vertex point.

34
Regular Tilings, contd
  • Do any regular polygons, besides n 3, 4, and 6,
    tile the plane?
  • Note Every regular tiling with n gt 6 must have
  • At least three vertex angles at each point
  • Vertex angles measuring more than 120
  • Angle measures at each vertex point that add to
    360

35
Regular Tilings, contd
  • In a previous question, you determined that a
    regular pentagon does not tile the plane.
  • Since 3(120) 360, no polygon with vertex
    angles larger than 120 i.e. n gt 6 can form a
    regular tiling.
  • Conclusion The only regular tilings are those
    for n 3, n 4, and n 6.

36
Vertex Figures
  • A vertex figure of a tiling is the polygon formed
    when line segments join consecutive midpoints of
    the sides of the polygons sharing that vertex
    point.

37
Vertex Figures, contd
  • Vertex figures for the three regular tilings are
    shown below.

38
Semiregular Tilings
  • Semiregular tilings
  • Are edge-to-edge tilings.
  • Use two or more regular polygonal regions.
  • Vertex figures are the same shape and size no
    matter where in the tiling they are drawn.

39
Example 7
  • Verify that the tiling shown is a semiregular
    tiling.

40
Example 7, contd
  • Solution
  • The tiling is made of 3 regular polygons.
  • Every vertex figure is the same shape and size.

41
Example 8
  • Verify that the tiling shown is not a semiregular
    tiling.

42
Example 8, contd
  • Solution
  • The tiling is made of 3 regular polygons.
  • Every vertex figure is not the same shape and
    size.

43
Semiregular Tilings
44
Miscellaneous Tilings
  • Tilings can also be made of other types of
    shapes.
  • Tilings consisting of irregular polygons that are
    all the same size and shape will be considered.

45
Miscellaneous Tilings, contd
  • Any triangle will tile the plane.
  • An example is given below

46
Miscellaneous Tilings, contd
  • Any quadrilateral (4-gon) will tile the plane.
  • An example is given below

47
Miscellaneous Tilings, contd
  • Some irregular pentagons (5-gons) will tile the
    plane.
  • An example is given below

48
Miscellaneous Tilings, contd
  • Some irregular hexagons (6-gons) will tile the
    plane.
  • An example is given below

49
Miscellaneous Tilings, contd
  • A polygonal region is convex if, for any two
    points in the region, the line segment having the
    two points as endpoints also lies in the region.
  • A polygonal region that is not convex is called
    concave.

50
Miscellaneous Tilings, contd
51
Pythagorean Theorem
  • In a right triangle, the sum of the areas of the
    squares on the sides of the triangle is equal to
    the area of the square on the hypotenuse.

52
Example 9
  • Find the length x in the figure.
  • Solution Use the theorem.

53
Pythagorean Theorem Converse
  • If
  • then the triangle is a right triangle.

54
Example 10
  • Show that any triangle with sides of length 3, 4
    and 5 is a right triangle.
  • Solution The longest side must be the
    hypotenuse. Let a 3, b 4, and c 5. We
    find

55
2.1 Initial Problem Solution
  • The tiling consists of squares and regular
    octagons.
  • The vertex angle measures add up to 90 2(135)
    360.
  • This is an example of one of the eight possible
    semiregular tilings.

56
Section 2.2Symmetry, Rigid Motions, and Escher
Patterns
  • Goals
  • Study symmetries
  • One-dimensional patterns
  • Two-dimensional patterns
  • Study rigid motions
  • Study Escher patterns

57
Symmetry
  • We say a figure has symmetry if it can be moved
    in such a way that the resulting figure looks
    identical to the original figure.
  • Types of symmetry that will be studied here are
  • Reflection symmetry
  • Rotation symmetry
  • Translation symmetry

58
Strip Patterns
  • An example of a strip pattern, also called a
    one-dimensional pattern, is shown below.

59
Strip Patterns, contd
  • This strip pattern has vertical reflection
    symmetry because the pattern looks the same when
    it is reflected across a vertical line.
  • The dashed line is called a line of symmetry.

60
Strip Patterns, contd
  • This strip pattern has horizontal reflection
    symmetry because the pattern looks the same when
    it is reflected across a horizontal line.

61
Strip Patterns, contd
  • This strip pattern has rotation symmetry because
    the pattern looks the same when it is rotated
    180 about a given point.
  • The point around which the pattern is turned is
    called the center of rotation.
  • Note that the degree of rotation must be less
    than 360.

62
Strip Patterns, contd
  • This strip pattern has translation symmetry
    because the pattern looks the same when it is
    translated a certain amount to the right.
  • The pattern is understood to extend indefinitely
    to the left and right.

63
Example 1
  • Describe the symmetries of the pattern.
  • Solution This pattern has translation symmetry
    only.

64
Question
  • Describe the symmetries of the strip pattern,
    assuming it continues to the left and right
    indefinitely
  • a. horizontal reflection, vertical reflection,
    translation
  • b. vertical reflection, translation
  • c. translation
  • d. vertical reflection

65
Two-Dimensional Patterns
  • Two-dimensional patterns that fill the plane can
    also have symmetries.
  • The pattern shown here has horizontal and
    vertical reflection symmetries.
  • Some lines of symmetry have been drawn in.

66
Two-Dimensional Patterns, contd
  • The pattern also has
  • horizontal and vertical translation symmetries.
  • 180 rotation symmetry.

67
Two-Dimensional Patterns, contd
  • This pattern has
  • 120 rotation symmetry.
  • 240 rotation symmetry.

68
Rigid Motions
  • Any combination of translations, reflections
    across lines, and/or rotations around a point is
    called a rigid motion, or an isometry.
  • Rigid motions may change the location of the
    figure in the plane.
  • Rigid motions do not change the size or shape of
    the figure.

69
Reflection
  • A reflection with respect to line l is defined as
    follows, with A being the image of point A under
    the reflection.
  • If A is a point on the line l, A A.
  • If A is not on line l, then l is the
    perpendicular bisector of line AA.

70
Example 2
  • Find the image of the triangle under reflection
    about the line l.

71
Example 2, contd
  • Solution
  • Find the image of each vertex point of the
    triangle, using a protractor.
  • A and A are equal distances from l.
  • Connect the image points to form the new triangle.

72
Vectors
  • A vector is a directed line segment.
  • One endpoint is the beginning point.
  • The other endpoint, labeled with an arrow, is the
    ending point.
  • Two vectors are equivalent if they are
  • Parallel
  • Have the same length
  • Point in the same direction.

73
Vectors, contd
  • A vector v is has a length and a direction, as
    shown below.
  • A translation can be defined by moving every
    point of a figure the distance and direction
    indicated by a vector.

74
Translation
  • A translation is defined as follows.
  • A vector v assigns to every point A an image
    point A.
  • The directed line segment between A and A is
    equivalent to v.

75
Example 3
  • Find the image of the triangle under a
    translation determined by the vector v.

76
Example 3, contd
  • Solution
  • Find the image of each vertex point by drawing
    the three vectors.
  • Connect the image points to form the new triangle.

77
Rotation
  • A rotation involves turning a figure around a
    point O, clockwise or counterclockwise, through
    an angle less than 360.

78
Rotation, contd
  • The point O is called the center of rotation.
  • The directed angle indicates the amount and
    direction of the rotation.
  • A positive angle indicates a counterclockwise
    rotation.
  • A negative angle indicates a clockwise rotation.
  • A point and its image are the same distance from
    O.

79
Rotation, contd
  • A rotation of a point X about the center O
    determined by a directed angle ?AOB is
    illustrated in the figure below.

80
Example 4
  • Find the image of the triangle under the given
    rotation.

81
Example 4, contd
  • Solution
  • Create a 50 angle with initial side OA.
  • Mark A on the terminal side, recalling that A
    and A are the same distance from O.

82
Example 4, contd
  • Solution contd
  • Repeat this process for each vertex.
  • Connect the three image points to form the new
    triangle.

83
Glide Reflection
  • A glide reflection is the result of a reflection
    followed by a translation.
  • The line of reflection must not be perpendicular
    to the translation vector.
  • The line of reflection is usually parallel to the
    translation vector.

84
Example 5
  • A strip pattern of footprints can be created
    using a glide reflection.

85
Crystallographic Classification
  • The rigid motions can be used to classify strip
    patterns.

86
Classification, contd
  • There are only seven basic one-dimensional
    repeated patterns.

87
Example 6
  • Use the crystallographic system to describe the
    strip pattern.
  • Solution The classification is pmm2.

88
Example 7
  • Use the crystallographic system to describe the
    strip pattern.
  • Solution The classification is p111.

89
Question
  • Use the crystallographic classification system
    to describe the pattern.
  • a. p112
  • b. pmm2
  • c. p1m1
  • d. p111

90
Escher Patterns
  • Maurits Escher was an artist who used rigid
    motions in his work.
  • You can view some examples of Eschers work in
    your textbook.

91
Escher Patterns, contd
  • An example of the process used to create
    Escher-type patterns is shown next.
  • Begin with a square.
  • Cut a piece from the upper left and translate it
    to the right.
  • Reflect the left side to the right side.

92
Escher Patterns, contd
  • The figure has been decorated and repeated.
  • Notice that the pattern has vertical and
    horizontal translation symmetry and vertical
    reflection symmetry.

93
Section 2.3Fibonacci Numbers and the Golden Mean
  • Goals
  • Study the Fibonacci Sequence
  • Recursive sequences
  • Fibonacci number occurrences in nature
  • Geometric recursion
  • The golden ratio

94
2.3 Initial Problem
  • This expression is called a continued fraction.
  • How can you find the exact decimal equivalent of
    this number?
  • The solution will be given at the end of the
    section.

95
Sequences
  • A sequence is an ordered collection of numbers.
  • A sequence can be written in the form a1,
    a2, a3, , an,
  • The symbol a1 represents the first number in the
    sequence.
  • The symbol an represents the nth number in the
    sequence.

96
Question
  • Given the sequence 1, 3, 5, 7, 9, 11, 13, 15,
    , find the values of the numbers A1, A3, and A9.
  • a. A1 1, A3 5, A9 15
  • b. A1 1, A3 3, A9 17
  • c. A1 1, A3 5, A9 17
  • d. A1 1, A3 5, A9 16

97
Fibonacci Sequence
  • The famous Fibonacci sequence is the result of a
    question posed by Leonardo de Fibonacci, a
    mathematician during the Middle Ages.
  • If you begin with one pair of rabbits on the
    first day of the year, how many pairs of rabbits
    will you have on the first day of the next year?
  • It is assumed that each pair of rabbits produces
    a new pair every month and each new pair begins
    to produce two months after birth.

98
Fibonacci Sequence, contd
  • The solution to this question is shown in the
    table below.
  • The sequence that appears three times in the
    table, 1, 1, 2, 3, 5, 8, 13, 21, is called the
    Fibonacci sequence.

99
Fibonacci Sequence, contd
  • The Fibonacci sequence is the sequence of numbers
    1, 1, 2, 3, 5, 8, 13, 21,
  • The Fibonacci sequence is found many places in
    nature.
  • Any number in the sequence is called a Fibonacci
    number.
  • The sequence is usually written
    f1, f2, f3, , fn,

100
Recursion
  • Recursion, in a sequence, indicates that each
    number in the sequence is found using previous
    numbers in the sequence.
  • Some sequences, such as the Fibonacci sequence,
    are generated by a recursion rule along with
    starting values for the first two, or more,
    numbers in the sequence.

101
Question
  • A recursive sequence uses the rule An 4An-1
    An-2, with starting values of A1 2, A2 7.
  • What is the fourth term in the sequence?
  • a. A4 45 c. A4 67
  • b. A4 26 d. A4 30

102
Fibonacci Sequence, contd
  • For the Fibonacci sequence, the starting values
    are f1 1 and f2 1.
  • The recursion rule for the Fibonacci sequence is
  • Example Find the third number in the sequence
    using the formula.
  • Let n 3.

103
Example 1
  • Suppose a tree starts from one shoot that grows
    for two months and then sprouts a second branch.
    If each established branch begins to spout a new
    branch after one months growth, and if every new
    branch begins to sprout its own first new branch
    after two months growth, how many branches does
    the tree have at the end of the year?

104
Example 1, contd
  • Solution The number of branches each month in
    the first year is given in the table and drawn in
    the figure below.

105
Fibonacci Numbers In Nature
  • The Fibonacci numbers are found many places in
    the natural world, including
  • The number of flower petals.
  • The branching behavior of plants.
  • The growth patterns of sunflowers and pinecones.
  • It is believed that the spiral nature of plant
    growth accounts for this phenomenon.

106
Fibonacci Numbers In Nature, contd
  • The number of petals on a flower are often
    Fibonacci numbers.

107
Fibonacci Numbers In Nature, contd
  • Plants grow in a spiral pattern. The ratio of
    the number of spirals to the number of branches
    is called the phyllotactic ratio.
  • The numbers in the phyllotactic ratio are usually
    Fibonacci numbers.

108
Fibonacci Numbers In Nature, contd
  • Example The branch at right has a phyllotactic
    ratio of 3/8.
  • Both 3 and 8 are Fibonacci numbers.

109
Fibonacci Numbers In Nature, contd
  • Mature sunflowers have one set of spirals going
    clockwise and another set going counterclockwise.
  • The numbers of spirals in each set are usually a
    pair of adjacent Fibonacci numbers.
  • The most common number of spirals is 34 and 55.

110
Geometric Recursion
  • In addition to being used to generate a sequence,
    the recursion process can also be used to create
    shapes.
  • The process of building a figure step-by-step by
    repeating a rule is called geometric recursion.

111
Example 2
  • Beginning with a 1-by-1 square, form a sequence
    of rectangles by adding a square to the bottom,
    then to the right, then to the bottom, then to
    the right, and so on.
  • Draw the resulting rectangles.
  • What are the dimensions of the rectangles?

112
Example 2, contd
  • Solution
  • The first seven rectangles in the sequence are
    shown below.

113
Example 2, contd
  • Solution contd
  • Notice that the dimensions of each rectangle are
    consecutive Fibonacci numbers.

114
The Golden Ratio
  • Consider the ratios of pairs of consecutive
    Fibonacci numbers.
  • Some of the ratios are calculated in the table
    shown on the following slide.

115
The Golden Ratio, contd
116
The Golden Ratio, contd
  • The ratios of pairs of consecutive Fibonacci
    numbers are also represented in the graph below.
  • The ratios approach the dashed line which
    represents a number around 1.618.

117
The Golden Ratio, contd
  • The irrational number, approximately 1.618, is
    called the golden ratio.
  • Other names for the golden ratio include the
    golden section, the golden mean, and the divine
    proportion.
  • The golden ratio is represented by the Greek
    letter f, which is pronounced fe or fi.

118
The Golden Ratio, contd
  • The golden ratio has an exact value of
  • The golden ratio has been used in mathematics,
    art, and architecture for more than 2000 years.

119
Golden Rectangles
  • A golden rectangle has a ratio of the longer side
    to the shorter side that is the golden ratio.
  • Golden rectangles are used in architecture, art,
    and packaging.

120
Golden Rectangles, contd
  • The rectangle enclosing the diagram of the
    Parthenon is an example of a golden rectangle.

121
Creating a Golden Rectangle
  • Start with a square, WXYZ, that measures one unit
    on each side.
  • Label the midpoint of side WX as point M.

122
Creating a Golden Rectangle, contd
  1. Draw an arc centered at M with radius MY.
  2. Label the point P as shown.

123
Creating a Golden Rectangle, contd
  1. Draw a line perpendicular to WP.
  2. Extend ZY to meet this line, labeling point Q as
    shown. The completed rectangle is shown.

124
2.3 Initial Problem Solution
  • How can you find the exact decimal equivalent of
    this number?

125
Initial Problem Solution, contd
  • We can find the value of the continued fraction
    by using a recursion rule that generates a
    sequence of fractions.
  • The first term is
  • The recursion rule is

126
Initial Problem Solution, contd
  • We find
  • The first term is
  • The second term is

127
Initial Problem Solution, contd
  • The third term is
  • The fourth term is

128
Initial Problem Solution, contd
  • The fractions in this sequence are
  • 2, 3/2, 5/3, 8/5,
  • This is recognized to be the same as the ratios
    of consecutive pairs of Fibonacci numbers.
  • The numbers in this sequence of fractions get
    closer and closer to f.
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