3.4 QUANTIFICATION OF PROPOSITIONAL FUNCTIONS IN SEVERAL VARIABLES 107NEGATION OF PROPOSITIONAL
FUNCTIONS IN SEVERAL VARIABLESIn parts (a) and (b) of Theorem 1, Article 3.3, we saw how to formulate a
positive statement of the negation of universally and existentially quantified
predicates in one variable. We now extend this to propositional functions
of two variables; in particular, we look at propositions involving mixed
quantifiers.
EXAMPLE 4 Formulate a positive statement of the negation of
(W(~Y)HX, Y).
Solution We must find a quantified predicate equivalent to
- [(Vx)(Iy)p(x, y)] in which negation is not a main connective. Let s(x)
represent (3y)p(x, y). Then - [(Vx)(3y)p(x, y)] is the same as - [(Vx)(s(x))]
which, by Theorem l(a), Article 3.3, is equivalent to (3x)(-s(x)). But - s(x) in turn is - [(3y)p(x, y)] which, by Theorem l(b), Article 3.3, is
equivalent, for fixed x, to (Vy)(-p(x, y)). Hence our original statement - [(W(3y)p(x, y)] is equivalent to (3x)(vy)( -- p(x, Y)). €I
Example 4 indicates that a statement of the form (Vx)(3y)p(x, y) is negated
by changing V to 3,3 to V, and negating the predicate p(x, y). It is left to you
[Exercise 5(c)J to provide an argument, similar to that given in Example 4,
showing that the same process is used to negate (3x)(Vy)p(x, y). We sum-
marize these facts and deal, for the record, with negations of nonmixed
quantifiers as well in the next theorem:
THEOREM 3
For any propositional function p(x, y) in two variables:Like Theorem 2, Theorem 3 generalizes to propositional functions in
any finite number of variables. To negate a statement involving the predi-
cate p(x,, x,,... , x,), preceded by n quantifiers, we use the guiding rule:
Change each universal quantifier V to 3, change each existential
quantifier 3 to V, and negate the predicate.EXAMPLE 5 Express the negation of (Vw)(3~)(3y)(Vz)p(w, x, y, z) in a form
that does not have negation as a main connective.
Soh tion By the preceding principle, - [(Vw)(3x)(3 y)(Vz)p(w, x, y, z)] is
equivalent to (3w)(Vx)(V y)(3z)(- p(w, x, y, z)). 0