Rosen 1.3

Predicate Calculus Rosen 1.3

Propositional Functions • Propositional functions (or predicates) are propositions that contain variables. • Ex: Let P(x) denote x > 3 • P(x) has no truth value until the variable x is bound by either • assigning it a value or by • quantifying it.

Assignment of values Let Q(x,y) denote “x + y = 7”. Each of the following can be determined as T or F. Q(4,3) Q(3,2) Q(4,3)  Q(3,2) [Q(4,3)  Q(3,2)]

Quantifiers Universe of Discourse, U: The domain of a variable in a propositional function. Universal Quantification of P(x) is the proposition:“P(x) is true for all values of x in U.” Existential Quantification of P(x) is the proposition: “There exists an element, x, in U such that P(x) is true.”

Universal Quantification of P(x) xP(x) “for all x P(x)” “for every x P(x)” Defined as: P(x0)  P(x1)  P(x2)  P(x3)  . . . for all xi in U Example: Let P(x) denote x2  x If U is x such that 0 < x < 1 then xP(x) is false. If U is x such that 1 < x then xP(x) is true.

Existential Quantification of P(x) xP(x) “there is an x such that P(x)” “there is at least one x such that P(x)” “there exists at least one x such that P(x)” Defined as: P(x0)  P(x1)  P(x2)  P(x3)  . . . for all xi in U Example: Let P(x) denote x2  x If U is x such that 0 < x  1 then xP(x) is true. If U is x such that x < 1 then xP(x) is true.

Quantifiers • xP(x) • True when P(x) is true for every x. • False if there is an x for which P(x) is false. • xP(x) • True if there exists an x for which P(x) is true. • False if P(x) is false for every x.

Negation (it is not the case) • xP(x) equivalent to xP(x) • True when P(x) is false for every x • False if there is an x for which P(x) is true. •  xP(x) is equivalent to xP(x) • True if there exists an x for which P(x) is false. • False if P(x) is true for every x.

Examples 2a Let T(a,b) denote the propositional function “a trusts b.” Let U be the set of all people in the world. Everybody trusts Bob. xT(x,Bob) Could also say: xU T(x,Bob)  denotes membership Bob trusts somebody. xT(Bob,x)

Examples 2b Alice trusts herself. T(Alice, Alice) Alice trusts nobody. x T(Alice,x) Carol trusts everyone trusted by David. x(T(David,x)  T(Carol,x)) Everyone trusts somebody. x y T(x,y)

Examples 2c x y T(x,y) Someone trusts everybody. y x T(x,y) Somebody is trusted by everybody. Bob trusts only Alice. x (x=Alice  T(Bob,x))

Bob trusts only Alice.x (x=Alice  T(Bob,x)) Let p be “x=Alice” q be “Bob trusts x” p q p  q T T T T F F F T F F F T True only when Bob trusts Alice or Bob does not trust someone who is not Alice

Quantification of Two Variables(read left to right) • xyP(x,y) or yxP(x,y) • True when P(x,y) is true for every pair x,y. • False if there is a pair x,y for which P(x,y) is false. • xyP(x,y) or yxP(x,y) • True if there is a pair x,y for which P(x,y) is true. • False if P(x,y) is false for every pair x,y.

Quantification of Two Variables • xyP(x,y) • True when for every x there is a y for which P(x,y) is true. • (in this case y can depend on x) • False if there is an x such that P(x,y) is false for every y. • yxP(x,y) • True if there is a y for which P(x,y) is true for every x. • (i.e., true for a particular y regardless (or independent) of x) • False if for every y there is an x for which P(x,y) is false. • Note that order matters here • In particular, if yxP(x,y) is true, then xyP(x,y) is true. • However, if xyP(x,y) is true, it is not necessary that yxP(x,y) is true.

Examples 3a Let L(x,y) be the statement “x loves y” where U for both x and y is the set of all people in the world. Everybody loves Jerry. xL(x,Jerry) Everybody loves somebody. x yL(x,y) There is somebody whom everybody loves. yxL(x,y)

Examples 3b1 There is somebody whom Lydia does not love. xL(Lydia,x) Nobody loves everybody. (For each person there is at least one person they do not love.) xyL(x,y) There is somebody (one or more) whom nobody loves y x L(x,y)

Examples 3b2 There is exactly one person whom everybody loves. xyL(y,x)? No. There could be more than one person everybody loves x{yL(y,x)  w[(yL(y,w))  w=x]} If there are, say, two values x1 and x2 (or more) for which L(y,x) is true, the proposition is false. x{yL(y,x)  w[(yL(y,w))  w=x]}? xw[(y L(y,w))  w=x]?

Examples 3c There are exactly two people whom Lynn loves. x y{xy  L(Lynn,x)  L(Lynn,y)}? No. x y{xy  L(Lynn,x)  L(Lynn,y)  z[L(Lynn,z) (z=x  z=y)]} Everyone loves himself or herself. xL(x,x) There is someone who loves no one besides himself or herself. xy(L(x,y)  x=y)

Thinking of Quantification as Loops • Quantifications of more than one variable can be thought of as nested loops. • For example, xyP(x,y) can be thought of as a loop over x, inside of which we loop over y (i.e., for each value of x). • Likewise, xyP(x,y) can be thought of as a loop over x with a loop over y nested inside. This can be extended to any number of variables.

Quantification as Loops • Using this procedure • xyP(x,y) is true if P(x,y) is true for all values of x,y as we loop through y for each value of x. • xyP(x,y) is true if P(x,y) is true for at least one set of values x,y as we loop through y for each value of x. • …And so on….

Quantification of 3 Variables • Let Q(x,y,z) be the statement “x + y = z”, where x,y,z are real numbers. • What is the truth values of • xyzQ(x,y,z)? • zxyQ(x,y,z)?

Quantification of 3 Variables • Let Q(x,y,z) be the statement “x + y = z”, where x,y,z are real numbers. • xyzQ(x,y,z) • is the statement, “For all real numbers x and for all real numbers y, there is a real number z such that • x + y = z.” True

Quantification of 3 Variables Let Q(x,y,z) be the statement “x + y = z”, where x,y,z are real numbers. zxyQ(x,y,z) is the statement, “There is a real number z such that for all real numbers x and for all real numbers y, x + y = z.” False

Examples 4a Let P(x) be the statement: “x is a Georgia Tech student” Q(x) be the statement: “ x is ignorant” R(x) be the statement: “x wears red” and U is the set of all people. No Georgia Tech students are ignorant. x(P(x) Q(x)) x(P(x) Q(x)) OK byImplication equivalence. x(P(x)  Q(x)) Does not work. Why?

Examples 4a No Georgia Tech students are ignorant. x(P(x) Q(x)) • x(P(x)  Q(x)) • x (P(x)  Q(x)) Negation equivalence • x ( P(x)  Q(x)) Implication equivalence • x (  P(x)   Q(x)) DeMorgans • x ( P(x)   Q(x)) Double negation Only true if everyone is a GT student and is not ignorant.

Examples 4a P(x) be the statement: “x is a Georgia Tech student” Q(x) be the statement: “ x is ignorant” R(x) be the statement: “x wears red” and U is the set of all people. No Georgia Tech students are ignorant. x(P(x)  Q(x)) Also works. Why?

Examples 4a No Georgia Tech students are ignorant. x(P(x) Q(x)) • x(P(x)  Q(x)) •  x (P(x)  Q(x)) Negation equivalence • x (P(x)  Q(x)) DeMorgan • x (P(x) Q(x)) Implication equivalence

Examples 4b Let P(x) be the statement: “x is a Georgia Tech student” Q(x) be the statement: “ x is ignorant” R(x) be the statement: “x wears red” and U is the set of all people. All ignorant people wear red. x(Q(x) R(x))

Examples 4c Let P(x) be the statement: “x is a Georgia Tech student” Q(x) be the statement: “ x is ignorant” R(x) be the statement: “x wears red” and U is the set of all people. No Georgia Tech student wears red. x(P(x) R(x)) What about this? x(R(x)  P(x))

Examples 4d If “no Georgia Tech students are ignorant” and “all ignorant people wear red”, does it follow that “no Georgia Tech student wears red?” x((P(x) Q(x))  (Q(x) R(x))) NO Some misguided GT student might wear red!! This can be shown with a truth table or Wenn diagrams

Rosen 1.3

Rosen 1.3

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Rosen 1.6

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Dean Rosen

Dr. Clive Rosen

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By Hayley Rosen

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Rosen-Zener Tunneling and Rosen-Zener Ramsey Interferometer

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Rosen 1.3

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Rosen 1.6, 1.7

Rosen 1.6

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