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Introduction to Predicates and Quantified Statements I Lecture 9 Section 2.1 Wed, Jan 31, 2007.

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1 Introduction to Predicates and Quantified Statements I Lecture 9 Section 2.1 Wed, Jan 31, 2007

2 Predicates A predicate is a sentence that contains a finite number of variables, and becomes a statement when values are substituted for the variables. If today is x, then Discrete Math meets today. The predicate becomes true when x = Wednesday.

3 Domains of Predicate Variables The domain D of a predicate variable x is the set of all values that x may take on. Let P(x) be the predicate. x is a free variable. The truth set of P(x) is the set of all values of x  D for which P(x) is true.

4 Domains of Predicate Variables In the previous example, we could define the domain of x to be D = {Sunday, Monday, Tuesday, Wednesday, Thursday, Friday, Saturday} Then the truth set of the predicate is S = {Monday, Tuesday, Wednesday, Friday}

5 The Universal Quantifier The symbol  is the universal quantifier. The statement  x  S, P(x) means “for all x in S, P(x),” where S  D. In this case, x is a bound variable, bound by the quantifier .

6 The Universal Quantifier The statement is true if P(x) is true for all x in S. The statement is false if P(x) is false for at least one x in S.

7 Examples Statement “7 is a prime number” is true. Predicate “x is a prime number” is neither true nor false. Statements “  x  {2, 3, 5, 7}, x is a prime number” is true. “  x  {2, 3, 6, 7}, x is a prime number” is false.

8 Examples of Universal Statements  x  {1, …, 10}, x 2 > 0.  x  {1, …, 10}, x 2 > 100.  x  R, x 3 – x  0.  x  R,  y  R, x 2 + xy + y 2  0.  x  , x 2 > 100.

9 Identities Algebraic identities are universal statements. When we write the algebraic identity (x + 1) 2 = x 2 + 2x + 1 what we mean is  x  R, (x + 1) 2 = x 2 + 2x + 1.

10 Identities DeMorgan’s Law ~(p  q)  (~p)  (~q) is equivalent to  p, q  {T, F}, ~(p  q) = (~p)  (~q).

11 The Existential Quantifier The symbol  is the existential quantifier. The statement  x  S, P(x) means “there exists x in S such that P(x),” where S  D. x is a bound variable, bound by the quantifier .

12 The Existential Quantifier The statement is true if P(x) is true for at least one x in S. The statement is false if P(x) is false for all x in S.

13 Examples of Universal Statements  x  {1, …, 10}, x 2 > 0.  x  {1, …, 10}, x 2 > 100.  x  R, x 3 – x  0.  x  R,  y  R, x 2 + xy + y 2  0.  x  , x 2 > 100.

14 Solving Equations An algebraic equation has a solution if there exists a value for x that makes it true.  x  R, (x + 1) 2 = x 2 + x + 2.

15 Boolean Expressions A boolean expression Is not a contradiction if there exist truth values for its variables that make it true. Is not a tautology if there exists truth values for its variables that make if false. The expression p  q  p  q. is neither a contradiction nor a tautology.

16 Universal Conditional Statements The statement  x  S, P(x)  Q(x) is a universal conditional statement. Example:  x  R, if x > 0, then x + 1/x  2. Example:  n  N,if n  13, then (½)n 2 + 3n – 4 > 8n + 12.

17 Universal Conditional Statements Suppose that predicates P(x) and Q(x) have the same domain D. If P(x)  Q(x) for all x in the truth set of P(x), then we write P(x)  Q(x).

18 Examples x > 0  x + 1/x  2. n is a multiple of 6  n is a multiple of 2 and n is a multiple of 3. n is a multiple of 8  n is a multiple of 2 and n is a multiple of 4.

19 Universal Biconditional Statements Again, suppose that predicates P(x) and Q(x) have the same domain D. If P(x)  Q(x) for all x in the truth set of P(x), then we write P(x)  Q(x).

20 Examples Which of the following are true? x > 0  x + 1/x  2. n is a multiple of 6  n is a multiple of 2 and n is a multiple of 3. n is a multiple of 8  n is a multiple of 2 and n is a multiple of 4.

21 Solving Algebraic Equations Steps in solving algebraic equations are equivalent to universal conditional statements. The step x + 3 = 8  x = 5 is justified by the statement x + 3 = 8  x = 5.

22 Solving Algebraic Equations An algebraic step from P(x) to Q(x) is reversible only if P(x)  Q(x). Reversible steps Adding 1 to both sides. Taking logarithms. Not reversible steps Squaring both sides. Multiplying by an arbitrary constant.

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