RL
Uploaded byRaechel Lim
PPT, PDF462 views

3.2 geometry the language of size and shape

Geometry began with ancient Egyptians and Babylonians using practical measurements and Pythagorean relationships in construction. Greeks like Euclid later formalized geometry, establishing five postulates including the parallel postulate. Many unsuccessfully tried to prove this postulate, leading to non-Euclidean geometries developed by Bolyai, Lobachevsky, and others. These geometries have different properties than Euclidean geometry and opened new areas of mathematical exploration. Fractal geometry, developed by Mandelbrot, describes naturally occurring structures through fractional dimensions and infinite complexity across all scales.

Embed presentation

Download to read offline
GEOMETRY: THE LANGUAGE OF SIZE AND SHAPE
A SHORT HISTORY The word "geometry" comes from two Greek words “geo” and “metria” meaning "earth measuring." In c. 2000 - 500 B.C. ancient Egyptians demonstrated a practical knowledge of geometry through surveying and construction projects.
Ancient clay tablets reveal that the Babylonians knew the Pythagorean relationships. In 750-250 B.C., Ancient Greeks practiced centuries of experimental geometry like Egypt and Babylonia had, and they absorbed the experimental geometry of both of those cultures. Then they created the first formal mathematics of any kind by organizing geometry with rules of logic. Around 300 BC, the geometry of Euclid was presented in its complete form in the book The Elements which formed the basis for
We could say that mathematics itself became an independent science with The Elements. (c. 400 B.C. - 1800 A. D.) When Euclid organized his thoughts on geometry, he chose four undefined terms (point, line, plane, space) assumed relations, and five axioms or postulates. From here he logically deduced theorems or properties of lines triangles, circles, etc. Postulates (also called axioms) are basic assumptions - rules that seem
THE FIVE POSTULATES OF EUCLID The shortest distance between any two points is a straight line. Any line segment can be extended infinitely in either direction. A circle can be made with any center and any radius. All right angles are equal to each other. Given a point and a line not on the point, only one line can be drawn parallel to the given line through the given point
Euclid was not satisfied with accepting the Fifth Postulate (also known as the Parallel Postulate) without proof. Many mathematicians throughout the next centuries unsuccessfully attempted to prove Euclid's Fifth. In c. 1600 A.D., Descartes made one of the greatest advances in geometry by connecting algebra and geometry. A myth is that he was watching a spider on the ceiling . Fermat also discovered coordinate geometry, but it is Descartes' version
While mathematicians tried proving the Fifth Postulates from the first four, they instead derived equivalent statements such as: Two parallel lines are equidistant. (Posidonius, 1st century BC) A line that intersects one of two parallel lines must also intersect the other line. (Proclus, 410-485 AD) For each triangle, one can form construct a similar triangle of any size. (Wallis, 1616-1703) The sum of the angles in a triangle is equal to two right angles. Three non-collinear points determine a circle.
The Fifth Postulate could not be deduced from the first four postulates. Thus it is possible to replace P5 with another postulate, and together with the first four, another type of geometry may be devised. Johann Bolyai (1802-1860) and Nikolai Lobachevsky (1792-1856) are credited with devising the first non-euclidean geometries, which is called hyperbolic geometry. A model of hyperbolic geometry is due to Jules Henri Poincare (1854-1912). He introduced the upper half plane model and open unit disc model.
SOME RESULTS FROM HYPERBOLIC GEOMETRY If L is a line and P a point not on L, then there are infinitely many lines through P that do not meet L. The sum of the interior angles of a triangle is less than 180 degrees.
ESCHER’S CIRCLE LIMIT III
HYPERBOLIC GEOMETRY IN NATURE
ELLIPTIC GEOMETRY Pioneered by Bernhard Riemann and Ludwig Schlafli Original form was spherical geometry or Riemmanian geometry Treats lines as great circles on the surface of a sphere (examples are geodesics) Any two great circles intersect at exactly two points
SOME RESULTS IN ELLIPTIC GEOMETRY If L is a line and P a point not on L, then there are infinitely many lines through P that meet L. The sum of the interior angles of a triangle is more than 180 degrees.
TOPOLOGY: THE RUBBER SHEET GEOMETRY A Greek word which means “study of place” The word “Topologie” was first introduced by Johann Benedict Listing Formally began in 1736 when Leonhard Euler introduced the “Seven Bridge Problem” Study of properties that are preserved under continuous deformation of objects such as stretching or bending but no tearing or gluing A donut can be turned into a cup...
IN THE LATE 1800’S - 1900’S Differential geometry - combines geometry with the techniques of calculus to provide a method for studying geometry on curved surfaces. Gauss and Riemann (his student) laid the foundation of this field. Einstein credits Gauss with formulating the mathematical fundamentals of the theory of relativity. Fractal Geometry - Fractals are geometric figures that model many natural structures like ferns or clouds. They are complex and detailed in structure at any level of their magnification. Often fractals are self-similar—that is, they have the property that each small portion of the fractal can be viewed as a reduced-scale replica of the whole.
One example of a fractal is the “snowflake” curve constructed by taking an equilateral triangle and repeatedly erecting smaller equilateral triangles on the middle third of the progressively smaller sides. Theoretically, the result would be a figure of finite area but with a perimeter of infinite length, consisting of an infinite number of vertices. In mathematical terms, such a curve cannot be differentiated.
•A turning point in the study of fractals came with the discovery of fractal geometry by the Polish-born French mathematician Benoit B. Mandelbrot in the 1970s. Mandelbrot adopted a much more abstract definition of dimension than that used in Euclidean geometry, stating that the dimension of a fractal must be used as an exponent when measuring its size.
The result is that a fractal cannot be treated as existing strictly in one, two, or any other whole- number dimensions. Instead, it must be handled mathematically as though it has some fractional dimension. The “snowflake” curve of fractals has a dimension of 1.2618. Fractal geometry is not simply an abstract development. A coastline, if measured down to its least irregularity, would tend toward infinite length just as does the “snowflake” curve. Mandelbrot has suggested that mountains, clouds, galaxy clusters, and other natural phenomena are similarly fractal in nature, and fractal geometry's application in the sciences has become a rapidly expanding field. In addition, the beauty of fractals has made them a key element in computer graphics.
Fractals have also been used to compress still and video images on computers. In 1987, English-born mathematician Dr. Michael F. Barnsley discovered the Fractal TransformTM which automatically detects fractal codes in real-world images (digitized photographs). The discovery spawned fractal image compression, used in a variety of multimedia and other image- based computer applications. One of the most intricate and beautiful images in all of mathematics is the Mandelbrot set, discovered by Benoit Mandelbrot in 1980.
3.2 geometry the language of size and shape

More Related Content

PPSX
History Of Mathematics
byBennet Hailink
 
PPTX
Modern geometry
bySFYC
 
PPTX
18th CENTURY MATHEMATICS
byHeidemae Remata
 
PPT
math in daily life
bysudharsan11
 
DOCX
Greek Mathematics
byJo Engira Jothi Jothi
 
PPTX
7 euclidean&non euclidean geometry
bypinspiration
 
PDF
History Of Non Euclidean Geometry
bydr.f
 
PPTX
The European Renaissance_History Of Mathematics(Rigino)
byRigino Macunay Jr.
 
History Of Mathematics
byBennet Hailink
 
Modern geometry
bySFYC
 
18th CENTURY MATHEMATICS
byHeidemae Remata
 
math in daily life
bysudharsan11
 
Greek Mathematics
byJo Engira Jothi Jothi
 
7 euclidean&non euclidean geometry
bypinspiration
 
History Of Non Euclidean Geometry
bydr.f
 
The European Renaissance_History Of Mathematics(Rigino)
byRigino Macunay Jr.
 

What's hot

PPTX
Math is the mother of all Science
byNafiulIslamNakib
 
PPT
Contribution of mathematicians by Pratima Nayak
byPratima Nayak ,Kendriya Vidyalaya Sangathan
 
PPTX
Mathematics in Ancient Greece
bySugarShyneOtaza
 
DOCX
Chinese Mathematics
byJo Engira Jothi Jothi
 
PPTX
The importance of mathematics
byNiño Zedrhic Villanueva
 
PPTX
Axioms, postulates
bypreetisangwan4
 
PPTX
History of Number Theory
byVolkan Nazife
 
PPTX
Wonders in maths
byjonnadulamanjula
 
PDF
History of Math
byGordana Divic
 
DOCX
Greek mathematician
byJohn Christian James Arellano
 
PPTX
History Of Mathematics
byGrenada High School
 
PPTX
Greek mathematics
bybooksrock
 
PPTX
Applications of maths in our daily life
byAbhinav Somani
 
PPTX
Sadiq maths ppt
byZia, Cadet College Kohat, Pakistan
 
PPTX
The Role of Mathematics In Human Daily Life
byAnna Osmanay
 
PDF
medieval European mathematics
bydhayjanebananlopez
 
PDF
Mathematics in the Modern World
byKylyn Albay
 
PPTX
Neutral Geometry_part2.pptx
byArna Jean
 
PPT
Ppt Project Math
byJessica Gokey
 
PPTX
Ancient math
bySheena Joy Patoc
 
Math is the mother of all Science
byNafiulIslamNakib
 
Contribution of mathematicians by Pratima Nayak
byPratima Nayak ,Kendriya Vidyalaya Sangathan
 
Mathematics in Ancient Greece
bySugarShyneOtaza
 
Chinese Mathematics
byJo Engira Jothi Jothi
 
The importance of mathematics
byNiño Zedrhic Villanueva
 
Axioms, postulates
bypreetisangwan4
 
History of Number Theory
byVolkan Nazife
 
Wonders in maths
byjonnadulamanjula
 
History of Math
byGordana Divic
 
Greek mathematician
byJohn Christian James Arellano
 
History Of Mathematics
byGrenada High School
 
Greek mathematics
bybooksrock
 
Applications of maths in our daily life
byAbhinav Somani
 
Sadiq maths ppt
byZia, Cadet College Kohat, Pakistan
 
The Role of Mathematics In Human Daily Life
byAnna Osmanay
 
medieval European mathematics
bydhayjanebananlopez
 
Mathematics in the Modern World
byKylyn Albay
 
Neutral Geometry_part2.pptx
byArna Jean
 
Ppt Project Math
byJessica Gokey
 
Ancient math
bySheena Joy Patoc
 

Viewers also liked

PDF
Module 6 geometry of shape and size
bydionesioable
 
PDF
Module 3 geometry of shape and size
bydionesioable
 
PDF
Module 4 geometry of shape and size
bydionesioable
 
PDF
Module 5 geometry of shape and size
bydionesioable
 
PDF
Module 2 geometry of shape and size
bydionesioable
 
PDF
Module 1 geometry of shape and size
bydionesioable
 
PDF
Modyul 17 mga suliranin, isyu, at programang pangkaunlaran
bydionesioable
 
PDF
Modyul 12 sektor ng agrikultuta, industriya at pangangalak
bydionesioable
 
Module 6 geometry of shape and size
bydionesioable
 
Module 3 geometry of shape and size
bydionesioable
 
Module 4 geometry of shape and size
bydionesioable
 
Module 5 geometry of shape and size
bydionesioable
 
Module 2 geometry of shape and size
bydionesioable
 
Module 1 geometry of shape and size
bydionesioable
 
Modyul 17 mga suliranin, isyu, at programang pangkaunlaran
bydionesioable
 
Modyul 12 sektor ng agrikultuta, industriya at pangangalak
bydionesioable
 

Similar to 3.2 geometry the language of size and shape

DOCX
Geometry
byLovely Ann Caluag
 
DOCX
Geometry
byjuhnampz
 
DOCX
Reviewer-in-HOM.docx
byJulieLusuegro1
 
DOCX
with properties of space that are related with distance, shape, .docx
byfranknwest27899
 
PPTX
Maths
byAshish Yadav
 
PPTX
Yash group Maths PPT for class IX
byYash Jangra
 
PPTX
Historical events in geometry
bySrishti Garg
 
PPT
HISTORY of GEOMETRY.ppt
byCheeneeRivera
 
PPTX
Intro to Geometry
bycmorgancavo
 
PPTX
482687029-The-Beginning-Of-Greek-Mathematics-pptx.pptx
bysharamaenacario
 
PPTX
CLASS 9 MATHS GEOMETRY INTRODUCTION TO EUCLID'S GEOMETRY.pptx
bymota55
 
PPTX
Famous Mathematicians
bySanketh Sanki
 
PPTX
Victoria.pptx
bybenbelmonte73
 
PDF
b.) GeometryThe old problem of proving Euclid’s Fifth Postulate.pdf
byannaindustries
 
PPTX
Geometric Bonanza
byJudson Jude
 
PPTX
NON-EUCLIDEAN GEOMETRY- Carl Friedrich Gaus.pptx
byCesarLongasaRobin
 
PDF
Topology As Fluid Geometry Twodimensional Spaces Volume 2 James W Cannon
byulwsbyuch091
 
PPTX
Axioms and Postulates of Euclid (non euclidean).pptx
byNecroManXer
 
PPTX
Beige White Orange Simple All About Triangles Presentation .pptx
bygeraldomaas75
 
PPTX
GEOMETRY AROUND US
byRaj Kumar
 
Geometry
byLovely Ann Caluag
 
Geometry
byjuhnampz
 
Reviewer-in-HOM.docx
byJulieLusuegro1
 
with properties of space that are related with distance, shape, .docx
byfranknwest27899
 
Maths
byAshish Yadav
 
Yash group Maths PPT for class IX
byYash Jangra
 
Historical events in geometry
bySrishti Garg
 
HISTORY of GEOMETRY.ppt
byCheeneeRivera
 
Intro to Geometry
bycmorgancavo
 
482687029-The-Beginning-Of-Greek-Mathematics-pptx.pptx
bysharamaenacario
 
CLASS 9 MATHS GEOMETRY INTRODUCTION TO EUCLID'S GEOMETRY.pptx
bymota55
 
Famous Mathematicians
bySanketh Sanki
 
Victoria.pptx
bybenbelmonte73
 
b.) GeometryThe old problem of proving Euclid’s Fifth Postulate.pdf
byannaindustries
 
Geometric Bonanza
byJudson Jude
 
NON-EUCLIDEAN GEOMETRY- Carl Friedrich Gaus.pptx
byCesarLongasaRobin
 
Topology As Fluid Geometry Twodimensional Spaces Volume 2 James W Cannon
byulwsbyuch091
 
Axioms and Postulates of Euclid (non euclidean).pptx
byNecroManXer
 
Beige White Orange Simple All About Triangles Presentation .pptx
bygeraldomaas75
 
GEOMETRY AROUND US
byRaj Kumar
 

More from Raechel Lim

PPTX
Chapter 1 (part1)
byRaechel Lim
 
PPTX
Chapter 1 (part 4)
byRaechel Lim
 
PPTX
Chapter 1 (part 3)
byRaechel Lim
 
PPTX
chapter 1 (part 2)
byRaechel Lim
 
PPT
3.3 calculus the language of change
byRaechel Lim
 
PPT
3.1 algebra the language of mathematics
byRaechel Lim
 
PPT
2.3 problem solving strategies
byRaechel Lim
 
PPTX
2.2 measurements, estimations and errors(part 2)
byRaechel Lim
 
PPS
2.1 numbers and their practical applications(part 2)
byRaechel Lim
 
PPT
2.1 lbd numbers and their practical applications
byRaechel Lim
 
PDF
Supp exer 18
byRaechel Lim
 
PDF
Supp exer 17
byRaechel Lim
 
PDF
Supp exer 16
byRaechel Lim
 
PDF
Supp exer 15
byRaechel Lim
 
PDF
Supp exer 14
byRaechel Lim
 
PDF
Supp exer 13
byRaechel Lim
 
PDF
Exercie 12 (take home)
byRaechel Lim
 
Chapter 1 (part1)
byRaechel Lim
 
Chapter 1 (part 4)
byRaechel Lim
 
Chapter 1 (part 3)
byRaechel Lim
 
chapter 1 (part 2)
byRaechel Lim
 
3.3 calculus the language of change
byRaechel Lim
 
3.1 algebra the language of mathematics
byRaechel Lim
 
2.3 problem solving strategies
byRaechel Lim
 
2.2 measurements, estimations and errors(part 2)
byRaechel Lim
 
2.1 numbers and their practical applications(part 2)
byRaechel Lim
 
2.1 lbd numbers and their practical applications
byRaechel Lim
 
Supp exer 18
byRaechel Lim
 
Supp exer 17
byRaechel Lim
 
Supp exer 16
byRaechel Lim
 
Supp exer 15
byRaechel Lim
 
Supp exer 14
byRaechel Lim
 
Supp exer 13
byRaechel Lim
 
Exercie 12 (take home)
byRaechel Lim
 

Recently uploaded

PPTX
Coefficient of Multiple Correlation - R₁.₂₃, R₂.₁₃ & R₃.₁₂
bySundar B N
 
PPTX
How to Create a Spreadsheet in Odoo 18
byCeline George
 
PPTX
TAMIS & TEMS - HOW, WHY and THE STEPS IN PROCTOLOGY
byJohn Thanakumar
 
PDF
Cultivating Greatness Pune's Best Preschools and Schools.pdf
byWellington College
 
PPTX
Introduction-to-Anatomy-and-Physiology.pptx
byAshish Umale
 
PDF
SIHMA Scalabrini Institute for Human Mobility in Africa(SIHMA) - Annual Repor...
byScalabrini Institute for Human Mobility in Africa
 
PPTX
UNIT 1: COMMUNICATION SKILLS, BARRIERS TO COMMUNICATION, PERSPECTIVES IN COMM...
byPOOJA KARVANDE
 
PPTX
Partial Correlation of Coefficient - Values of r₁₂.₃, r₂₃.₁ & r₁₃.₂
bySundar B N
 
PDF
Comprehensive Principles, Design Techniques, and Applications of Electronic O...
byGS Virdi
 
PPTX
Overview of how to Create a Model in Odoo 18
byCeline George
 
PPTX
Planning Assessment for Outcome-based Education
byAdri Jovin
 
PPTX
REVISED DEFENSE MECHANISM / ADJUSTMENT MECHANISM-FINAL
byShimla
 
PDF
IMANI Africa files RTI request seeking full disclosure on 2026 SIM registrati...
bynservice241
 
PPTX
B. Pharmacy Unit-3 (Fats and Oils Reaction and Analytical Constant)
bySandeshSul
 
PDF
Advanced Process Flow and Micromachining Techniques for MEMS Fabrication: A D...
byGS Virdi
 
PDF
Multiple Myeloma , definition, etiology, PP, CM , DE and management
byNisha Borsa
 
PPTX
Steve Hale - Developing Elite Young Goalkeepers 2024.pptx
bypjmfd
 
PPTX
Industrial production, estimation and utilization of the following phytoconst...
byD. Y. Patil College of Pharmacy, Kolhapur.
 
PDF
The voice of the rain poem class 11th.pdf
byReeta Baral
 
PPTX
Isolation, Identification and Analysis of phytoconstituents.
byD. Y. Patil College of Pharmacy, Kolhapur.
 
Coefficient of Multiple Correlation - R₁.₂₃, R₂.₁₃ & R₃.₁₂
bySundar B N
 
How to Create a Spreadsheet in Odoo 18
byCeline George
 
TAMIS & TEMS - HOW, WHY and THE STEPS IN PROCTOLOGY
byJohn Thanakumar
 
Cultivating Greatness Pune's Best Preschools and Schools.pdf
byWellington College
 
Introduction-to-Anatomy-and-Physiology.pptx
byAshish Umale
 
SIHMA Scalabrini Institute for Human Mobility in Africa(SIHMA) - Annual Repor...
byScalabrini Institute for Human Mobility in Africa
 
UNIT 1: COMMUNICATION SKILLS, BARRIERS TO COMMUNICATION, PERSPECTIVES IN COMM...
byPOOJA KARVANDE
 
Partial Correlation of Coefficient - Values of r₁₂.₃, r₂₃.₁ & r₁₃.₂
bySundar B N
 
Comprehensive Principles, Design Techniques, and Applications of Electronic O...
byGS Virdi
 
Overview of how to Create a Model in Odoo 18
byCeline George
 
Planning Assessment for Outcome-based Education
byAdri Jovin
 
REVISED DEFENSE MECHANISM / ADJUSTMENT MECHANISM-FINAL
byShimla
 
IMANI Africa files RTI request seeking full disclosure on 2026 SIM registrati...
bynservice241
 
B. Pharmacy Unit-3 (Fats and Oils Reaction and Analytical Constant)
bySandeshSul
 
Advanced Process Flow and Micromachining Techniques for MEMS Fabrication: A D...
byGS Virdi
 
Multiple Myeloma , definition, etiology, PP, CM , DE and management
byNisha Borsa
 
Steve Hale - Developing Elite Young Goalkeepers 2024.pptx
bypjmfd
 
Industrial production, estimation and utilization of the following phytoconst...
byD. Y. Patil College of Pharmacy, Kolhapur.
 
The voice of the rain poem class 11th.pdf
byReeta Baral
 
Isolation, Identification and Analysis of phytoconstituents.
byD. Y. Patil College of Pharmacy, Kolhapur.
 
In this document
Powered by AI
See More

Explores geometry as the language of size and shape.

Discusses the origins of geometry, its ancient practices, and the formalization by Euclid.

Details the five foundational postulates established by Euclid in geometry.

Describes attempts to prove the Fifth Postulate and the emergence of non-Euclidean geometry.

Highlights key results from hyperbolic geometry, including properties of angles in triangles.

Introduces applications of hyperbolic geometry in art and nature.

Presents elliptic geometry, focusing on spherical forms and their properties.

Describes key outcomes in elliptic geometry, specifically regarding triangle angles.

Introduces topology, its origins, and its study of properties under continuous deformation.

Covers the rise of differential and fractal geometry, merging geometry with calculus and complexity.

Explains fractal geometry's discovery, properties, and applications in nature and computer graphics.

3.2 geometry the language of size and shape

  • 1.
  • 2.
    A SHORT HISTORY Theword "geometry" comes from two Greek words “geo” and “metria” meaning "earth measuring." In c. 2000 - 500 B.C. ancient Egyptians demonstrated a practical knowledge of geometry through surveying and construction projects.
  • 3.
    Ancient clay tabletsreveal that the Babylonians knew the Pythagorean relationships. In 750-250 B.C., Ancient Greeks practiced centuries of experimental geometry like Egypt and Babylonia had, and they absorbed the experimental geometry of both of those cultures. Then they created the first formal mathematics of any kind by organizing geometry with rules of logic. Around 300 BC, the geometry of Euclid was presented in its complete form in the book The Elements which formed the basis for
  • 4.
    We could saythat mathematics itself became an independent science with The Elements. (c. 400 B.C. - 1800 A. D.) When Euclid organized his thoughts on geometry, he chose four undefined terms (point, line, plane, space) assumed relations, and five axioms or postulates. From here he logically deduced theorems or properties of lines triangles, circles, etc. Postulates (also called axioms) are basic assumptions - rules that seem
  • 5.
    THE FIVE POSTULATESOF EUCLID The shortest distance between any two points is a straight line. Any line segment can be extended infinitely in either direction. A circle can be made with any center and any radius. All right angles are equal to each other. Given a point and a line not on the point, only one line can be drawn parallel to the given line through the given point
  • 6.
    Euclid was notsatisfied with accepting the Fifth Postulate (also known as the Parallel Postulate) without proof. Many mathematicians throughout the next centuries unsuccessfully attempted to prove Euclid's Fifth. In c. 1600 A.D., Descartes made one of the greatest advances in geometry by connecting algebra and geometry. A myth is that he was watching a spider on the ceiling . Fermat also discovered coordinate geometry, but it is Descartes' version
  • 7.
    While mathematicians triedproving the Fifth Postulates from the first four, they instead derived equivalent statements such as: Two parallel lines are equidistant. (Posidonius, 1st century BC) A line that intersects one of two parallel lines must also intersect the other line. (Proclus, 410-485 AD) For each triangle, one can form construct a similar triangle of any size. (Wallis, 1616-1703) The sum of the angles in a triangle is equal to two right angles. Three non-collinear points determine a circle.
  • 8.
    The Fifth Postulatecould not be deduced from the first four postulates. Thus it is possible to replace P5 with another postulate, and together with the first four, another type of geometry may be devised. Johann Bolyai (1802-1860) and Nikolai Lobachevsky (1792-1856) are credited with devising the first non-euclidean geometries, which is called hyperbolic geometry. A model of hyperbolic geometry is due to Jules Henri Poincare (1854-1912). He introduced the upper half plane model and open unit disc model.
  • 9.
    SOME RESULTS FROMHYPERBOLIC GEOMETRY If L is a line and P a point not on L, then there are infinitely many lines through P that do not meet L. The sum of the interior angles of a triangle is less than 180 degrees.
  • 10.
  • 11.
  • 12.
    ELLIPTIC GEOMETRY Pioneered byBernhard Riemann and Ludwig Schlafli Original form was spherical geometry or Riemmanian geometry Treats lines as great circles on the surface of a sphere (examples are geodesics) Any two great circles intersect at exactly two points
  • 13.
    SOME RESULTS INELLIPTIC GEOMETRY If L is a line and P a point not on L, then there are infinitely many lines through P that meet L. The sum of the interior angles of a triangle is more than 180 degrees.
  • 14.
    TOPOLOGY: THE RUBBERSHEET GEOMETRY A Greek word which means “study of place” The word “Topologie” was first introduced by Johann Benedict Listing Formally began in 1736 when Leonhard Euler introduced the “Seven Bridge Problem” Study of properties that are preserved under continuous deformation of objects such as stretching or bending but no tearing or gluing A donut can be turned into a cup...
  • 15.
    IN THE LATE1800’S - 1900’S Differential geometry - combines geometry with the techniques of calculus to provide a method for studying geometry on curved surfaces. Gauss and Riemann (his student) laid the foundation of this field. Einstein credits Gauss with formulating the mathematical fundamentals of the theory of relativity. Fractal Geometry - Fractals are geometric figures that model many natural structures like ferns or clouds. They are complex and detailed in structure at any level of their magnification. Often fractals are self-similar—that is, they have the property that each small portion of the fractal can be viewed as a reduced-scale replica of the whole.
  • 16.
    One example ofa fractal is the “snowflake” curve constructed by taking an equilateral triangle and repeatedly erecting smaller equilateral triangles on the middle third of the progressively smaller sides. Theoretically, the result would be a figure of finite area but with a perimeter of infinite length, consisting of an infinite number of vertices. In mathematical terms, such a curve cannot be differentiated.
  • 18.
    •A turning pointin the study of fractals came with the discovery of fractal geometry by the Polish-born French mathematician Benoit B. Mandelbrot in the 1970s. Mandelbrot adopted a much more abstract definition of dimension than that used in Euclidean geometry, stating that the dimension of a fractal must be used as an exponent when measuring its size.
  • 19.
    The result isthat a fractal cannot be treated as existing strictly in one, two, or any other whole- number dimensions. Instead, it must be handled mathematically as though it has some fractional dimension. The “snowflake” curve of fractals has a dimension of 1.2618. Fractal geometry is not simply an abstract development. A coastline, if measured down to its least irregularity, would tend toward infinite length just as does the “snowflake” curve. Mandelbrot has suggested that mountains, clouds, galaxy clusters, and other natural phenomena are similarly fractal in nature, and fractal geometry's application in the sciences has become a rapidly expanding field. In addition, the beauty of fractals has made them a key element in computer graphics.
  • 20.
    Fractals have alsobeen used to compress still and video images on computers. In 1987, English-born mathematician Dr. Michael F. Barnsley discovered the Fractal TransformTM which automatically detects fractal codes in real-world images (digitized photographs). The discovery spawned fractal image compression, used in a variety of multimedia and other image- based computer applications. One of the most intricate and beautiful images in all of mathematics is the Mandelbrot set, discovered by Benoit Mandelbrot in 1980.