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Proofs Using Logical Equivalences. Rosen 1.2. List of Logical Equivalences. p T p; pF p Identity Laws pT T; pF F Domination Laws pp p; pp p Idempotent Laws (p) p Double Negation Law pq qp; pq qp Commutative Laws
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Proofs Using Logical Equivalences Rosen 1.2
List of Logical Equivalences pT p; pF p Identity Laws pT T; pF F Domination Laws pp p; pp p Idempotent Laws (p) p Double Negation Law pq qp; pq qp Commutative Laws (pq) r p (qr); (pq) r p (qr) Associative Laws
List of Equivalences p(qr) (pq)(pr) Distribution Laws p(qr) (pq)(pr) (pq)(p q) De Morgan’s Laws (pq)(p q) Miscellaneous p p T Or Tautology p p F And Contradiction (pq) (p q) Implication Equivalence pq(pq) (qp) Biconditional Equivalence
The Proof Process Assumptions -Definitions -Already-proved equivalences -Statements (e.g., arithmetic or algebraic) Logical Steps Conclusion (That which was to be proved)
Prove: (pq) q pq (pq) q Left-Hand Statement q (pq) Commutative (qp) (q q) Distributive (qp) T Or Tautology qp Identity pq Commutative Begin with exactly the left-hand side statement End with exactly what is on the right Justify EVERY step with a logical equivalence
Prove: (pq) q pq (pq) q Left-Hand Statement q (pq) Commutative • (qp) (q q) Distributive Why did we need this step? Our logical equivalence specified that is distributive on the right. This does not guarantee the equivalence works on the left! Ex.: Matrix multiplication is not always commutative (Note that whether or not is distributive on the left is not the point here.)
Prove: p q q p Contrapositive p q p q Implication Equivalence q p Commutative (q) p Double Negation q p Implication Equivalence
Prove: p p q is a tautologyMust show that the statement is true for any value of p,q. p p q p (p q) Implication Equivalence (p p) q Associative (p p) q Commutative T q Or Tautology q T Commutative • T Domination This tautology is called the addition rule of inference.
Why do I have to justify everything? • Note that your operation must have the same order of operands as the rule you quote unless you have already proven (and cite the proof) that order is not important. • 3+4 = 4+3 • 3/4 4/3 • A*B B*A for everything (for example, matrix multiplication)
Prove: (pq) p is a tautology (pq) p (pq) p Implication Equivalence (pq) p DeMorgan’s (qp) p Commutative q (p p) Associative q (p p) Commutative q T Or Tautology T Domination
Prove or Disprove p q p q ??? To prove that something is not true it is enough to provide one counter-example. (Something that is true must be true in every case.) p q pq pq F T T F The statements are not logically equivalent
Prove:p qp q p q (pq) (qp) Biconditional Equivalence (pq) (qp) Implication Equivalence (x2) (pq) (qp) Double Negation (qp) (pq) Commutative (qp) (pq) Double Negation (qp) (pq) Implication Equivalence (x2) p q Biconditional Equivalence