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Discrete Mathematics

Discrete Mathematics. Mathematical Reasoning Methods of Proof. University of Jazeera College of Information Technology & Design Khulood Ghazal. Nature & Importance of Proofs. In mathematics, a proof is: A sequence of statements that form an argument.

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Discrete Mathematics

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  1. Discrete Mathematics Mathematical Reasoning Methods of Proof University of Jazeera College of Information Technology & Design Khulood Ghazal

  2. Nature & Importance of Proofs • In mathematics, a proof is: • A sequence of statements that form an argument. • Must be correct (well-reasoned, logically valid) and complete (clear, detailed) that establishes the truth of a mathematical statement. • Why must the argument be correct & complete? • Correctness prevents us from fooling ourselves. • Completeness allows anyone to verify the result.

  3. Rules of Inference • Rules of inference are patterns of logically valid deductions from hypotheses to conclusions. • We will review “inference rules” (i.e., correct & fallacious), and “proof methods”.

  4. Inference Rules - General Form • Inference Rule – • Pattern establishing that if we know that a set of hypotheses are all true, then a certain related conclusion statement is true. Hypothesis 1 Hypothesis 2 …  conclusion “” means “therefore”

  5. Inference Rules & Implications • Each logical inference rule corresponds to an implication that is a tautology. • Hypothesis 1 Inference rule Hypothesis 2 …  conclusion • Corresponding tautology: ((Hypoth. 1)  (Hypoth. 2)  …)  conclusion

  6. Some Inference Rules • pRule of Addition  pqp pq • “It is below freezing now. Therefore, it is either below freezing or raining now.” • pqRule of Simplification  p p ^ q p • “It is below freezing and raining now. Therefore, it is below freezing now.

  7. Some Inference Rules p q  pqRule of Conjunction • (p) ^ (q) (p ^q ) • “It is below freezing. • It is raining now. • Therefore, it is below freezing and it is raining now.

  8. Modus Ponens & Tollens • p Rule of modus ponenspq(p^(p q) q)q “If it is snowing today, then we will go skiing” and “It is snowing today” imply “We will go skiing” • q pqRule of modus tollensp (q ^(p q) p)

  9. Syllogism Inference Rules • pqRule of hypotheticalqrsyllogism ((pq) ^ (qr ) (pr) )pr • p  q Rule of disjunctive p syllogism ((p  q)^ p q) q

  10. Formal Proofs • A formal proof of a conclusion C, given premises p1, p2,…,pnconsists of a sequence of steps, each of which applies some inference rule to premises or to previously-proven statements (as hypotheses) to yield a new true statement (the conclusion). • A proof demonstrates that if the premises are true, then the conclusion is true (i.e., valid argument).

  11. Formal Proof - Example • Suppose we have the following premises:“It is not sunny and it is cold.”“if it is not sunny, we will not swim”“If we do not swim, then we will canoe.”“If we canoe, then we will be home early.” • Given these premises, prove the theorem“We will be home early” using inference rules.

  12. Proof Example cont. • Let us adopt the following abbreviations: sunny = “It is sunny”; cold = “It is cold”; swim = “We will swim”; canoe = “We will canoe”; early = “We will be home early”. • Then, the premises can be written as:(1) sunny  cold • (2) sunny  swim(3) swim  canoe • (4) canoe  early

  13. Proof Example cont. • StepProved by1. sunny  cold Premise #1.2. sunny Simplification of 1 .3. sunny  swim Premise #2.4. swim Modus tollens on 2,3.5. swimcanoe Premise #3.6. canoe Modus ponens on 4,5.7. canoeearlyPremise #4.8. early Modus ponens on 6,7.

  14. Proof Methods • Proving pq • Direct proof: Assume p is true, and prove q. • Indirect proof: Assume q, and prove p. • Trivial proof: Prove q true. • Proving p • Proof by contradiction: Prove p (r  r) (r  ris a contradiction); therefore p must be false. • Prove (a  b)  p • Proof by cases: prove (a p) and (b p).

  15. Direct Proof Example • Definition: An integer n is called oddiffn=2k+1 for some integer k; n is eveniffn=2k for some k. • Theorem: (For all numbers n) If n is an odd integer, then n2 is an odd integer. • Proof: If n is odd, then n = 2k+1 for some integer k. • Thus, n2 = (2k+1)2 = 4k2 + 4k + 1 = 2(2k2 + 2k) + 1. Therefore n2 is of the form 2j + 1 (with j the integer 2k2 + 2k), thus n2 is odd.

  16. Indirect Proof • Proving pq • Indirect proof: Assume q, and prove p.

  17. Indirect Proof Example • Theorem: (For all integers n) If 3n+2 is odd, then n is odd. • Proof: Suppose that the conclusion is false, i.e., that n is even. Then n=2k for some integer k. Then 3n+2 = 3(2k)+2 = 6k+2 = 2(3k+1). Thus 3n+2 is even, because it equals 2j for integer j = 3k+1. So 3n+2 is not odd. We have shown that ¬(n is odd)→¬(3n+2 is odd), thus its contra-positive (3n+2 is odd) → (n is odd) is also true.

  18. Trivial Proof • Proving pq • Trivial proof: Prove q true.

  19. Trivial Proof Example • Theorem: (For integers n) If n is the sum of two prime numbers, then either n is odd or n is even. • Proof:Any integer n is either odd or even. So the conclusion of the implication is true regardless of the truth of the hypothesis. Thus the implication is true trivially.

  20. Proof by Contradiction • Proving p • Assume p, and prove that p (rr) • (rr) is a trivial contradiction, equal to F • Thus pF is true only if p=F

  21. Proof by Cases To prove we need to prove

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