Presentation is loading. Please wait.

Presentation is loading. Please wait.

CSE 311 Foundations of Computing I Lecture 8 Proofs Autumn 2012 CSE 311 1.

Published byMyra Perry Modified over 9 years ago

Similar presentations

Presentation on theme: "CSE 311 Foundations of Computing I Lecture 8 Proofs Autumn 2012 CSE 311 1."— Presentation transcript:

1 CSE 311 Foundations of Computing I Lecture 8 Proofs Autumn 2012 CSE 311 1

2 Announcements Reading assignments – Logical Inference 1.6, 1.7 7 th Edition 1.5, 1.6 6 th Edition 1.5, 3.1 5 th Edition Homework – HW 1 returned – Turn in HW2 Now! – HW3 available Autumn 2012CSE 311 2

3 Highlights from last lecture Autumn 2012CSE 311 3

4 Proofs Start with hypotheses and facts Use rules of inference to extend set of facts Result is proved when it is included in the set Autumn 2012CSE 3114 Fact 1 Fact 2 Hypothesis 3 Hypothesis 2 Hypothesis 1 Statement Result

5 An inference rule: Modus Ponens If p and p  q are both true then q must be true Write this rule as Given: – If it is Wednesday then you have 311 homework due today. – It is Wednesday. Therefore, by Modus Ponens: – You have 311 homework due today. Autumn 2012CSE 311 5 p, p  q ∴ q

6 Proofs Show that r follows from p, p  q, and q  r 1. p Given 2.p  q Given 3.q  r Given 4.q Modus Ponens from 1 and 2 5.r Modus Ponens from 3 and 4 Autumn 2012CSE 311 6

7 Inference Rules Each inference rule is written as which means that if both A and B are true then you can infer C and you can infer D. – For rule to be correct (A  B)  C and (A  B)  D must be a tautologies Sometimes rules don’t need anything to start with. These rules are called axioms: – e.g. Excluded Middle Axiom Autumn 2012CSE 311 7 A, B ∴ C,D ∴ p  p

8 Simple Propositional Inference Rules Excluded middle plus two inference rules per binary connective, one to eliminate it and one to introduce it Autumn 2012CSE 311 8 p  q ∴ p, q p, q ∴ p  q p ∴ p  q p  q,  p ∴ q p, p  q ∴ q p  q ∴ p  q ∴ p  p Direct Proof Rule Not like other rules! See next slide…

9 Direct Proof of an Implication p  q denotes a proof of q given p as an assumption. Don’t confuse with p  q. The direct proof rule – if you have such a proof then you can conclude that p  q is true E.g. Let’s prove p  (p  q) 1. p Assumption 2. p  q Intro for  from 1 3. p  (p  q) Direct proof rule Autumn 2012CSE 311 9 Proof subroutine for p  (p  q)

10 Example Prove ((p  q)  (q  r))  (p  r) Autumn 2012CSE 311 10

11 Proofs can use Equivalences too Show that  p follows from p  q and  q 1. p  q Given 2.  q Given 3.  q   p Contrapositive of 1 (Equivalence!) 4.  p Modus Ponens from 2 and 3 Autumn 2012CSE 311 11

12 Inference Rules for Quantifiers Autumn 2012CSE 311 12 P(c) for some c ∴  x P(x)  x P(x) ∴ P(a) for any a “Let a be anything * ”...P(a) ∴  x P(x)  x P(x) ∴ P(c) for some special c * in the domain of P

13 Proofs using Quantifiers “There exists an even prime number” Autumn 2012CSE 311 13 Prime(x): x is an integer > 1 and x is not a multiple of any integer strictly between 1 and x

14 Even and Odd Prove: “The square of every even number is even” Formal proof of:  x (Even(x)  Even(x 2 )) Autumn 2012CSE 311 14 Even(x)   y (x=2y) Odd(x)   y (x=2y+1) Domain: Integers

15 Even and Odd Prove: “The square of every odd number is odd” English proof of:  x (Odd(x)  Odd(x 2 )) Let x be an odd number. Then x=2k+1 for some integer k (depending on x) Therefore x 2 =(2k+1) 2 = 4k 2 +4k+1=2(2k 2 +2k)+1. Since 2k 2 +2k is an integer, x 2 is odd. Autumn 2012CSE 311 15 Even(x)   y (x=2y) Odd(x)   y (x=2y+1) Domain: Integers

16 “Proof by Contradiction”: One way to prove  p If we assume p and derive False (a contradiction) then we have proved  p. 1. p Assumption... 3. F 4. p  F Direct Proof rule 5.  p  F Equivalence from 4 6.  p Equivalence from 5 Autumn 2012CSE 311 16

17 Even and Odd Prove: “No number is both even and odd” English proof:   x (Even(x)  Odd(x))  x  (Even(x)  Odd(x)) Let x be any integer and suppose that it is both even and odd. Then x=2k for some integer k and x=2n+1 for some integer n. Therefore 2k=2n+1 and hence k=n+½. But two integers cannot differ by ½ so this is a contradiction. Autumn 2012CSE 311 17 Even(x)   y (x=2y) Odd(x)   y (x=2y+1) Domain: Integers

18 Rational Numbers A real number x is rational iff there exist integers p and q with q  0 such that x=p/q. Prove: – If x and y are rational then xy is rational Autumn 2012CSE 311 18 Rational(x)   p  q ((x=p/q)  Integer(p)  Integer(q)  q  0)  x  y ((Rational(x)  Rational(y))  Rational(xy)) Domain: Real numbers

19 Rational Numbers A real number x is rational iff there exist integers p and q with q  0 such that x=p/q. Prove: – If x and y are rational then xy is rational – If x and y are rational then x+y is rational Autumn 2012CSE 311 19 Rational(x)   p  q ((x=p/q)  Integer(p)  Integer(q)  q  0)

20 Rational Numbers A real number x is rational iff there exist integers p and q with q  0 such that x=p/q. Prove: – If x and y are rational then xy is rational – If x and y are rational then x+y is rational – If x and y are rational then x/y is rational Autumn 2012CSE 311 20 Rational(x)   p  q ((x=p/q)  Integer(p)  Integer(q)  q  0)

21 Counterexamples To disprove  x P(x) find a counterexample – some c such that  P(c) – works because this implies  x  P(x) which is equivalent to  x P(x) Autumn 2012CSE 311 21

22 Proofs Formal proofs follow simple well-defined rules and should be easy to check – In the same way that code should be easy to execute English proofs correspond to those rules but are designed to be easier for humans to read – Easily checkable in principle Simple proof strategies already do a lot – Later we will cover a specific strategy that applies to loops and recursion (mathematical induction) Autumn 2012CSE 311 22

Download ppt "CSE 311 Foundations of Computing I Lecture 8 Proofs Autumn 2012 CSE 311 1."

Similar presentations

Discrete Math Methods of proof 1.

Discrete Math Methods of proof 1.
Introduction to Proofs

Introduction to Proofs
Proofs, Recursion and Analysis of Algorithms Mathematical Structures for Computer Science Chapter 2 Copyright © 2006 W.H. Freeman & Co.MSCS SlidesProofs,

Proofs, Recursion and Analysis of Algorithms Mathematical Structures for Computer Science Chapter 2 Copyright © 2006 W.H. Freeman & Co.MSCS SlidesProofs,
Discussion #131/18 Discussion #13 Induction (the process of deriving generalities from particulars) Mathematical Induction (deductive reasoning over the.

Discussion #131/18 Discussion #13 Induction (the process of deriving generalities from particulars) Mathematical Induction (deductive reasoning over the.
Logic and Proof. Argument An argument is a sequence of statements. All statements but the first one are called assumptions or hypothesis. The final statement.

Logic and Proof. Argument An argument is a sequence of statements. All statements but the first one are called assumptions or hypothesis. The final statement.
CSE115/ENGR160 Discrete Mathematics 01/31/12 Ming-Hsuan Yang UC Merced 1.

CSE115/ENGR160 Discrete Mathematics 01/31/12 Ming-Hsuan Yang UC Merced 1.
CSE115/ENGR160 Discrete Mathematics 02/01/11

CSE115/ENGR160 Discrete Mathematics 02/01/11
Logic: Connectives AND OR NOT P Q (P ^ Q) T F P Q (P v Q) T F P ~P T F

Logic: Connectives AND OR NOT P Q (P ^ Q) T F P Q (P v Q) T F P ~P T F
CSE 311 Foundations of Computing I Lecture 6 Predicate Logic Autumn 2011 CSE 3111.

CSE 311 Foundations of Computing I Lecture 6 Predicate Logic Autumn 2011 CSE 3111.
Copyright © Zeph Grunschlag,

Copyright © Zeph Grunschlag,
Proofs, Recursion and Analysis of Algorithms Mathematical Structures for Computer Science Chapter 2.1 Copyright © 2006 W.H. Freeman & Co.MSCS SlidesProofs,

Proofs, Recursion and Analysis of Algorithms Mathematical Structures for Computer Science Chapter 2.1 Copyright © 2006 W.H. Freeman & Co.MSCS SlidesProofs,
Proof by Deduction. Deductions and Formal Proofs A deduction is a sequence of logic statements, each of which is known or assumed to be true A formal.

Proof by Deduction. Deductions and Formal Proofs A deduction is a sequence of logic statements, each of which is known or assumed to be true A formal.
Introduction to Proofs ch. 1.6, pg. 87,93 Muhammad Arief download dari

Introduction to Proofs ch. 1.6, pg. 87,93 Muhammad Arief download dari
EE1J2 – Discrete Maths Lecture 5 Analysis of arguments (continued) More example proofs Formalisation of arguments in natural language Proof by contradiction.

EE1J2 – Discrete Maths Lecture 5 Analysis of arguments (continued) More example proofs Formalisation of arguments in natural language Proof by contradiction.
Mathematical Induction Assume that we are given an infinite supply of stamps of two different denominations, 3 cents and and 5 cents. Prove using mathematical.

Mathematical Induction Assume that we are given an infinite supply of stamps of two different denominations, 3 cents and and 5 cents. Prove using mathematical.
CSE 311 Foundations of Computing I Lecture 6 Predicate Logic, Logical Inference Spring 2013 1.

CSE 311 Foundations of Computing I Lecture 6 Predicate Logic, Logical Inference Spring
Methods of Proof & Proof Strategies

Methods of Proof & Proof Strategies
CSCI 115 Chapter 2 Logic. CSCI 115 §2.1 Propositions and Logical Operations.

CSCI 115 Chapter 2 Logic. CSCI 115 §2.1 Propositions and Logical Operations.
Introduction to Proofs

Introduction to Proofs
Reading and Writing Mathematical Proofs

Reading and Writing Mathematical Proofs

Similar presentations

Ads by Google