Presentation is loading. Please wait.

Presentation is loading. Please wait.

A Very Practical Series 1 What if we also save a fixed amount (d) every year?

Published bySydney Bryant Modified over 8 years ago

Similar presentations

Presentation on theme: "A Very Practical Series 1 What if we also save a fixed amount (d) every year?"— Presentation transcript:

1 A Very Practical Series 1 What if we also save a fixed amount (d) every year?

2 Formulate the Recurrence Relation 2 Let r = interest rate, d = amount saved annually. Let k = 1+r.

3 Formulate the Recurrence Relation 3 Let r = interest rate, d = amount saved annually. Let k = 1+r.

4 Infinite Sets and Cardinality 4

5 Infinite Sets and Cardinality 5 The Schroeder-Bernstein Theorem: If then. (We will use this result w/o proof.) (Bijection)

6 Infinite Sets and Cardinality 6

7 Apparent Paradoxes 7

8 Apparent Paradoxes 8 -4-2024 31024

9 Apparent Paradoxes 9 -4-2024 31024 Clearly(?) one-to-one and onto.

10 Apparent Paradoxes 10

11 Apparent Paradoxes A proper subset of a finite set has a smaller cardinality than the whole set. A proper subset of an infinite set can have the same cardinality as the whole set. – | Even_Integers | = | Z | = ℵ 0. Hilbert’s “Grand Hotel”. 11

12 The Rational Numbers are Countable 12 Consider positive rational numbers first

13 13

14 14

15 15

16 16

17 17

18 18

19 19

20 20 +

21 21 +

22 22 +

23 23 +

24 Question Are you convinced by this proof that the set of positive rationals, Q +, is countable? –(A) Yes! That’s really clever! –(B) Hmm... Why is this surprising? –(C) Hmm... What about duplicate values in Grid? –(D) I want to see what to do with negative rational numbers. –(E) I just don’t get it. 24

25 What about negative rational numbers? Just use a different Grid. The set Q is countable. 25

26 The Real Numbers are Not Countable Proposition ¬C: R is not countable. Proposition C: R is countable. If R is countable, then (0,1) is countable. Then there is a 1-1 correspondence between Z + and (0,1). Let that correspondence be this table: Every r i ∈ (0,1) must be in this table. 26 1r 1 = 0.d 11 d 12 d 13 d 14... 2r 2 = 0.d 21 d 22 d 23 d 24... 3r 3 = 0.d 31 d 32 d 33 d 34... 4r 4 = 0.d 41 d 42 d 43 d 44......

27 The Real Numbers are Not Countable Proposition ¬C: R is not countable. Proposition C: R is countable. If R is countable, then (0,1) is countable. Then there is a 1-1 correspondence between Z + and (0,1). Let that correspondence be this table: Every r i ∈ (0,1) must be in this table. 27 1r 1 = 0.d 11 d 12 d 13 d 14... 2r 2 = 0.d 21 d 22 d 23 d 24... 3r 3 = 0.d 31 d 32 d 33 d 34... 4r 4 = 0.d 41 d 42 d 43 d 44......

28 The Real Numbers are Not Countable Proposition ¬C: R is not countable. Proposition C: R is countable. If R is countable, then (0,1) is countable. Then there is a 1-1 correspondence between Z + and (0,1). Let that correspondence be this table: Every r i ∈ (0,1) must be in this table. 28 1r 1 = 0.d 11 d 12 d 13 d 14... 2r 2 = 0.d 21 d 22 d 23 d 24... 3r 3 = 0.d 31 d 32 d 33 d 34... 4r 4 = 0.d 41 d 42 d 43 d 44......

29 The Real Numbers are Not Countable Proposition ¬C: R is not countable. Proposition C: R is countable. If R is countable, then (0,1) is countable. Then there is a 1-1 correspondence between Z + and (0,1). Let that correspondence be this table: Every r i ∈ (0,1) must be in this table. 29 1r 1 = 0.d 11 d 12 d 13 d 14... 2r 2 = 0.d 21 d 22 d 23 d 24... 3r 3 = 0.d 31 d 32 d 33 d 34... 4r 4 = 0.d 41 d 42 d 43 d 44......

30 The Real Numbers are Not Countable Proposition ¬C: R is not countable. Proposition C: R is countable. If R is countable, then (0,1) is countable. Then there is a 1-1 correspondence between Z + and (0,1). Let that correspondence be this table: Every r i ∈ (0,1) must be in this table. 30 1r 1 = 0.d 11 d 12 d 13 d 14... 2r 2 = 0.d 21 d 22 d 23 d 24... 3r 3 = 0.d 31 d 32 d 33 d 34... 4r 4 = 0.d 41 d 42 d 43 d 44......

31 The Real Numbers are Not Countable Proposition ¬C: R is not countable. Proposition C: R is countable. If R is countable, then (0,1) is countable. Then there is a 1-1 correspondence between Z + and (0,1). Let that correspondence be this table: Every r i ∈ (0,1) must be in this table. 31 1r 1 = 0.d 11 d 12 d 13 d 14... 2r 2 = 0.d 21 d 22 d 23 d 24... 3r 3 = 0.d 31 d 32 d 33 d 34... 4r 4 = 0.d 41 d 42 d 43 d 44......

32 The Real Numbers are Not Countable Construct a number x = 0. x 1 x 2 x 3 x 4... where each digit x i ≠ d ii, for every i. –Therefore, x ≠ r i, for every i. –So, x is not in the table. Even though x ∈ (0,1). Thus, Proposition C leads to a contradiction. –Therefore, Proposition ¬C is true: The set R is not countable. Q.E.D. –This is a diagonalization proof by contradiction. 32

33 The Real Numbers are Not Countable Construct a number x = 0. x 1 x 2 x 3 x 4... where each digit x i ≠ d ii, for every i. –Therefore, x ≠ r i, for every i. –So, x is not in the table. Even though x ∈ (0,1). Thus, Proposition C leads to a contradiction. –Therefore, Proposition ¬C is true: The set R is not countable. Q.E.D. –This is a diagonalization proof by contradiction. 33

34 The Real Numbers are Not Countable Construct a number x = 0. x 1 x 2 x 3 x 4... where each digit x i ≠ d ii, for every i. –Therefore, x ≠ r i, for every i. –So, x is not in the table. Even though x ∈ (0,1). Thus, Proposition C leads to a contradiction. –Therefore, Proposition ¬C is true: The set R is not countable. Q.E.D. –This is a diagonalization proof by contradiction. 34

35 Question Are you convinced by this proof, that the set R of real numbers is uncountable? –(A)Yes! That’s really clever! –(B)Hmph. Can’t you just add x to the table? –(C)Hmph. Can you write down that table? –(D)Hmph. Why does getting a contradiction from C mean that ¬C must be true? –(E)I just don’t get it. 35

Download ppt "A Very Practical Series 1 What if we also save a fixed amount (d) every year?"

Similar presentations

Countability. The cardinality of the set A is equal to the cardinality of a set B if there exists a bijection from A to B cardinality? bijection? injection.

Countability. The cardinality of the set A is equal to the cardinality of a set B if there exists a bijection from A to B cardinality? bijection? injection.
04/23/13 Countability Discrete Structures (CS 173) Derek Hoiem, University of Illinois 1.

04/23/13 Countability Discrete Structures (CS 173) Derek Hoiem, University of Illinois 1.
1 Diagonalization Fact: Many books exist. Fact: Some books contain the titles of other books within them. Fact: Some books contain their own titles within.

1 Diagonalization Fact: Many books exist. Fact: Some books contain the titles of other books within them. Fact: Some books contain their own titles within.
EE1J2 - Slide 1 EE1J2 – Discrete Maths Lecture 10 Cardinality Uncountability of the real numbers.

EE1J2 - Slide 1 EE1J2 – Discrete Maths Lecture 10 Cardinality Uncountability of the real numbers.
EE1J2 – Discrete Maths Lecture 9

EE1J2 – Discrete Maths Lecture 9
Introduction to Computability Theory

Introduction to Computability Theory
Courtesy Costas Busch - RPI1 A Universal Turing Machine.

Courtesy Costas Busch - RPI1 A Universal Turing Machine.
15-251 Great Theoretical Ideas in Computer Science.

Great Theoretical Ideas in Computer Science.
Module 5 Topics Proof of the existence of unsolvable problems

Module 5 Topics Proof of the existence of unsolvable problems
Functions f( ) = A B Lecture 15: Nov 4.

Functions f( ) = A B Lecture 15: Nov 4.
Fall 2004COMP 3351 A Universal Turing Machine. Fall 2004COMP 3352 Turing Machines are “hardwired” they execute only one program A limitation of Turing.

Fall 2004COMP 3351 A Universal Turing Machine. Fall 2004COMP 3352 Turing Machines are “hardwired” they execute only one program A limitation of Turing.
Lecture 13 3.2,3.3 Sequences & Summations Proof by Induction.

Lecture ,3.3 Sequences & Summations Proof by Induction.
1 Lecture 6 Topics –Proof of the existence of unsolvable problems Problems/languages not in REC Proof Technique –There are more problems/languages than.

1 Lecture 6 Topics –Proof of the existence of unsolvable problems Problems/languages not in REC Proof Technique –There are more problems/languages than.
Cardinality of a Set “The number of elements in a set.” Let A be a set. a.If A =  (the empty set), then the cardinality of A is 0. b. If A has exactly.

Cardinality of a Set “The number of elements in a set.” Let A be a set. a.If A =  (the empty set), then the cardinality of A is 0. b. If A has exactly.
CS 2210 (22C:019) Discrete Structures Sets and Functions Spring 2015 Sukumar Ghosh.

CS 2210 (22C:019) Discrete Structures Sets and Functions Spring 2015 Sukumar Ghosh.
15-251 Great Theoretical Ideas in Computer Science.

Great Theoretical Ideas in Computer Science.
Cantor’s Legacy: Infinity And Diagonalization Great Theoretical Ideas In Computer Science Steven RudichCS 15-251 Spring 2004 Lecture 25Apr 13, 2004Carnegie.

Cantor’s Legacy: Infinity And Diagonalization Great Theoretical Ideas In Computer Science Steven RudichCS Spring 2004 Lecture 25Apr 13, 2004Carnegie.
Cardinality of Sets Section 2.5.

Cardinality of Sets Section 2.5.
THE NATURE OF SETS Copyright © Cengage Learning. All rights reserved. 2.

THE NATURE OF SETS Copyright © Cengage Learning. All rights reserved. 2.
3.9.2015Relation, function 1 Mathematical logic Lesson 5 Relations, mappings, countable and uncountable sets.

Relation, function 1 Mathematical logic Lesson 5 Relations, mappings, countable and uncountable sets.

Similar presentations

Ads by Google