The Axiomatic Method. The axiomatic method I: Mathematical Proofs Why do we need to prove things? How do we resolve paradoxes?

Slides:



Advertisements
Similar presentations
By: Victoria Leffelman.  Any geometry that is different from Euclidean geometry  Consistent system of definitions, assumptions, and proofs that describe.
Advertisements

Axiomatic systems and Incidence Geometry
Learning through failure in mathematics.  Around 300 B.C., Euclid began work in Alexandria on Elements, a veritable “bible of mathematics”  Euclid.
Math 409/409G History of Mathematics Book I of the Elements Part I.
Chapter 1 Using Geogebra Exploration and Conjecture.
Greek Mathematics and Philosophy.  Thales ( BC): father of mathematical proof.
CS1001 Lecture 22. Overview Mechanizing Reasoning Mechanizing Reasoning G ö del ’ s Incompleteness Theorem G ö del ’ s Incompleteness Theorem.
Euclid BC Author of The Elements –13 books in all. –Standard textbook for Geometry for about 2000 years. Taught in Alexandria, Egypt.
So far we have learned about:
Euclid’s Elements: The first 4 axioms
Study Guide Timeline Euclid’s five axioms (300 BC) From Proclus (400AD) belief that the fifth axiom is derivable from the first four Saccheri (17 th century):
TR1413: Discrete Mathematics For Computer Science Lecture 1: Mathematical System.
What is Geometry? Make 2 lists with your table:
Non-Euclidean Geometries
Spherical Geometry and World Navigation
Euclid’s Plane Geometry
History of Mathematics
Chapter 2: Euclid’s Proof of the Pythagorean Theorem
Lecture 4, MATH 210G.03, Spring 2013 Greek Mathematics and Philosophy Period 1: 650 BC-400 BC (pre-Plato) Period 2: 400 BC – 300 BC (Plato, Euclid) Period.
Non-Euclidean Geometry Br. Joel Baumeyer, FSC Christian Brothers University.
Chapter 2 Midterm Review
Axiomatic systems By Micah McKee. VOCAB: Axiomatic system Postulate/Axiom Theorem Axiomatic system Line segment Ray Point Line Plane.
The Strange New Worlds: The Non-Euclidean Geometries Presented by: Melinda DeWald Kerry Barrett.
Chapter 9 Geometry © 2008 Pearson Addison-Wesley. All rights reserved.
Copyright © Cengage Learning. All rights reserved.
Math 3121 Abstract Algebra I Section 0: Sets. The axiomatic approach to Mathematics The notion of definition - from the text: "It is impossible to define.
Lecture 4, MATH 210G.02, Fall 2015 Greek Mathematics and Philosophy Goals: Learn a few of the theorems proved by Greek mathematicians Understand some of.
1 Those Incredible Greeks Lecture Three. 2 Outline  Hellenic and Hellenistic periods  Greek numerals  The rise of “modern” mathematics – axiomatic.
Chapter 2 Greek Geometry The Deductive Method The Regular Polyhedra Ruler and Compass Construction Conic Sections Higher-degree curves Biographical Notes:
MAT 333 Fall  As we discovered with the Pythagorean Theorem examples, we need a system of geometry to convince ourselves why theorems are true.
Michelle Huchette Block 2. * Greek * From Alexandria, taught mathematics there * Worked with prepositions and proofs * Created the basis for teachings.
INTRODUCTION TO Euclid’s geometry The origins of geometry.
Euclid’s Postulates 1.Two points determine one and only one straight line 2.A straight line extends indefinitely far in either direction 3. A circle may.
Mathematics. We tend to think of math as an island of certainty in a vast sea of subjectivity, interpretability and chaos. What is it?
TOK: Mathematics Unit 1 Day 1. Introduction Opening Question Is math discovered or is it invented? Think about it. Think real hard. Then discuss.
Contributions of Ancient Greece: Archimedes & Euclid Euclid Archimedes.
Biological Science.
H YPERSHOT : F UN WITH H YPERBOLIC G EOMETRY Praneet Sahgal.
Chapter 2 Construction  Proving. Historical Background Euclid’s Elements Greek mathematicians used  Straightedge  Compass – draw circles, copy distances.
Euclid and the “elements”. Euclid (300 BC, 265 BC (?) ) was a Greek mathematician, often referred to as the "Father of Geometry”. Of course this is not.
Non-Euclidean Geometry Part I.
The Non-Euclidean Geometries
§21.1 Parallelism The student will learn about: Euclidean parallelism,
The Parallel Postulate
What is Geometry? Make 2 lists with your table: What geometry content are you confident about? What geometry content are you nervous about?
INDUCTION Lecture 22 CS2110 – Fall 2009 A well-known scientist (some say it was Bertrand Russell) once gave a public lecture on astronomy. He described.
The reason why Euclid was known as the father of geometry because, he was responsible for assembling all the world’s knowledge of flat planes and 3D geometry.
Geometry 2.2 And Now From a New Angle.
Conditional Statements A conditional statement has two parts, the hypothesis and the conclusion. Written in if-then form: If it is Saturday, then it is.
TOK: Mathematics Unit 1 Day 1. 2 – B 2 = AB – B 2 Factorize both sides: (A+B)(A-B) = B(A-B) Divide both sides by (A-B): A = B = B Since A = B, B+B=B Add.
PROVING STATEMENTS IN GEOMETRY. WHAT IS A PROOF? A written account of the complete thought process that is used to reach a conclusion. Each step is supported.
Foundations of Geometry
Lecture 4, MATH 210G.02, Fall 2016 Greek Mathematics and Philosophy Goals: Learn a few of the theorems proved by Greek mathematicians Understand some of.
Geometry 2.2 And Now From a New Angle. 2.2 Special Angles and Postulates: Day 1  Objectives  Calculate the complement and supplement of an angle  Classify.
A historical introduction to the philosophy of mathematics
Lecture 4, MATH 210G.02, Fall 2017 Greek Mathematics and Philosophy
HYPERBOLIC GEOMETRY Paul Klotzle Gabe Richmond.
Euclid’s Postulates Two points determine one and only one straight line A straight line extends indefinitely far in either direction 3. A circle may be.
POSTULATES AND PROOFS ★Postulates are statements that are assumed to be true without proof. ★ Postulates serve two purposes - to explain undefined terms,
9.7 Non-Euclidean Geometries
Thinking Geometrically: Using Proofs
Euclid The Elements “There is no royal road to Geometry.”
Book 1, Proposition 29 By: Isabel Block and Alexander Clark
Lecture 22: Gödel’s Theorem CS200: Computer Science
The Elements, Book I – Propositions 22 – 28 MONT 104Q – Mathematical Journeys: Known to Unknown October 2, 2015.
An Ideal Euclidean Model
Induction Lecture 20 CS2110 – Spring 2013
Philosophy of Mathematics: a sneak peek
An example of the “axiomatic approach” from geometry
1.3 Early Definitions & Postulates
Presentation transcript:

The Axiomatic Method

The axiomatic method I: Mathematical Proofs Why do we need to prove things? How do we resolve paradoxes?

Eudlid’s “Elements” arranged in order many of Eudoxus's theorems, perfected many of Theaetetus's, and brought to irrefutable demonstration only loosely proved by his predecessors Ptolemy once asked him if there were a shorted way to study geometry than the Elements, … In his aim he was a Platonist, being in sympathy with this philosophy, whence he made the end of the whole "Elements" the construction of the so-called Platonic figures.

Elements begins with 5 postulates. Also … axioms Euclid calls 'common notions’… general assumptions that allow mathematics to proceed deductively. For example: “Things which are equal to the same thing are equal to each other.””

Euclid's Postulates 1. A straight line segment can be drawn joining any two points. 2. Any straight line segment can be extended indefinitely in a straight line. 3. Given any straight line segment, a circle can be drawn having the segment as radius and one endpoint as center. 4. All right angles are congruent. 5. If two lines are drawn which intersect a third in such a way that the sum of the inner angles on one side is less than two right angles, then the two lines inevitably must intersect each other on that side if extended far enough. This postulate is equivalent to what is known as the parallel postulate. Euclid's fifth postulate cannot be proven from others, though attempted by many people. Euclid used only 1—4 for the first 28 propositions of the Elements, but was forced to invoke the parallel postulate on the 29th. In 1823, Bolyai and Lobachevsky independently realized that entirely self-consistent "non-Euclidean geometries" could be created in which the parallel postulate did not hold.

Occam’s Razor the explanation of any phenomenon should make as few assumptions as possible, eliminating those that make no difference in the observable predictions of the explanatory hypothesis or theory. The principle is often expressed in Latin as the lexparsimoniae ("law of parsimony”

Turtles all the way down A well-known scientist … gave public lecture on astronomy… described how earth orbits around sun a sun orbits around center of galaxy. At the end of the lecture, a little old lady at the back of the room got up and said: "What you have told us is rubbish. The world is really a flat plate supported on the back of a giant tortoise.” Scientist replies, "What is tortoise standing on?" "You're very clever, young man" said the old lady. "But it's turtles all the way down!”

Mathematics vs Pure Reason What distinguishes mathematical reasoning from other reasoning? Exs: If I study hard I will get a good grade I think, therefore I am The area of a triangle is ½*b*h

Descartes: Scientific Method Descartes’ major work, published in 1637 “Discourse on the Method for Rightly Directing One’s Reason and Searching for Truth in the Sciences.” Descartes proposed that all science become demonstrative in the way Euclid made geometry demonstrative, namely as a series of valid deductions from self- evident truths, rather than as something rooted in observation and experiment.

Geometry, without the parallel postulate

Other geometries

Hyperbolic geometry

axiomatic method reduce a “coherent body” of mathematical to a minimal set of “axioms. In their Principia Mathematica, Whitehead and Bertrand Russell attempted to show that all mathematical theory could be reduced to some collection of axioms. The explication of the particular axioms can help to clarify a suitable level of mathematical abstraction (is the set of assumptions too many or not enough – compare this to Occam’s razor The Zermelo-Fraenkel axioms, the result of the axiomatic method applied to set theory, allowed the proper formulation of set theory problems and helped avoided the paradoxes of naïve set theory. One such problem was the Continuum hypothesis.

Peano axioms Peano axioms define properties natural numbers, N. 1. For every natural number x, x = x. (reflexive) 2. For all xand y, if x = y, then y = x (symmetric). 3. For all x, y and z, if x = y and y = z, then x = z (transitive). 4. For all a and b, if a is a natural number and a = b, then b is also a natural number. the naturals are assumed to be closed under a "successor" function S is a natural number. 6. For every natural number n, S(n) is a natural number. properties of S. 7. For every natural number n, S(n) ≠ For all m and n, if S(m) = S(n), then m = n. …the set of natural numbers is infinite, 9. If K is a set such that: * 0 is in K, and * for every natural number n, if n is in K, then S(n) is in K, then K contains every natural number.