Transcript APS09_0508
Section 5.8
Fibonacci
Sequence
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What You Will Learn
Fibonacci Sequence
5.8-2
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Fibonacci Sequence
This sequence is named after Leonardo
of Pisa, also known as Fibonacci.
He was one of the most distinguished
mathematicians of the Middle Ages.
He is also credited with introducing the
Hindu-Arabic number system into
Europe.
5.8-3
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Fibonacci Sequence
1, 1, 2, 3, 5, 8, 13, 21, …
In the Fibonacci sequence, the first two
terms are 1.
The sum of these two terms gives us
the third term (2).
The sum of the 2nd and 3rd terms give
us the 4th term (3) and so on.
5.8-4
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In Nature
In the middle of the 19th century,
mathematicians found strong
similarities between this sequence and
many natural phenomena.
The numbers appear in many seed
arrangements of plants and petal
counts of many flowers.
Fibonacci numbers are also observed in
the structure of pinecones and
pineapples.
5.8-5
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Golden Number
5 1
Golden Number :
2
The value obtained from the ratio of
the (n + 1) term to the nth term
preceding it in the Fibonacci sequence,
as n gets larger and larger.
The symbol for the Golden Number is
, the
Greek letter “phi.”
5.8-6
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Golden Ratio
A
C
B
The ratio of the whole, AB, to the larger
part, AC, is equal to the ratio of the
larger part AC, to the smaller part, CB.
AB is referred to as a golden ratio.
AC
AC
is referred to as a golden ratio.
CB
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Golden Proportion or Divine
Proportion
AB
AC
AC
CB
5.8-8
5 1
1.618
2
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Golden Ratio in Architecture
The Great Pyramid of Gizeh in Egypt,
built about 2600 B.C.
Ratio of any
side of the
square base to
the altitude is
about 1.611
5.8-9
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Golden Ratio in the Human Body
Architect Le
Corbusier
developed a scale
of proportions for
the human body
that he called the
Modulor.
5.8-10
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Golden Rectangle
A
C
B
a
a
a
b
length a b a
width
a
b
5 1
2
*Note: the new smaller rectangle is also a golden rectangle.
5.8-11
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Golden Rectangle in Nature
The curve derived from a succession of
diminishing golden rectangles is the
same as the spiral curve of the
chambered nautilus.
5.8-12
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Golden Rectangle in Greek
Architecture
5.8-13
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Golden Rectangle in Greek Art
Greek statues, vases, urns, and so on
also exhibit characteristics of the
golden ratio. It is for Phidas,
considered the greatest of Greek
sculptors, that the golden ratio was
named “phi.” The proportions can be
found abundantly in his work.
5.8-14
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Golden Rectangle in Art
The proportions of the golden
rectangle can be found in the work
many artists,
from the old
masters to
the moderns.
5.8-15
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Fibonacci Numbers in Music
An octave on a keyboard has 13 keys:
8 white keys and 5 black keys (the 5
black keys are in one group of 2 and
one group of 3).
In Western music, the
most complete scale,
the chromatic scale,
consists of 13 notes.
All are Fibonacci
numbers.
5.8-16
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Fibonacci Numbers in Music
Patterns that can be expressed
mathematically in terms of Fibonacci
relationships have been found in
Gregorian chants and works of many
composers, including Bach, Beethoven,
and Bartók. A number of twentiethcentury musical works, including Ernst
Krenek’s Fibonacci Mobile, were
deliberately structured by using
Fibonacci proportions.
5.8-17
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Why the Fibonacci Sequence?
A number of studies have tried to
explain why the Fibonacci sequence
and related items are linked to so
many real-life situations. It appears
that the Fibonacci numbers are a part
of a natural harmony that is pleasing
to both the eye and the ear.
5.8-18
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Why the Fibonacci Sequence?
In the nineteenth century, German
physicist and psychologist Gustav
Fechner tried to deter- mine which
dimensions were most pleasing to the
eye. Fechner, along with psychologist
Wilhelm Wundt, found that most
people do unconsciously favor golden
dimensions when purchasing greeting
cards, mirrors, and other rectangular
objects.
5.8-19
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