Basic Assumptions and Scope of Study

1. A Semantic Model for Vague Quantifiers Combining Fuzzy Theory and Supervaluation Theory Ka Fat CHOWThe Hong Kong Polytechnic University

2. Basic Assumptions and Scope of Study • Vagueness is manifested as degree of truth, which can be represented by a number in [0, 1]. • Classical tautologies / contradictions by virtue of classical logic / lexical meaning remain their status as tautologies / contradictions when the non-vague predicates are replaced by vague predicates • Do not consider the issue of higher order vagueness

3. Fuzzy Theory (FT) • Uses fuzzy sets to model vague concepts • ║p║ - truth value of p • ║x  S║ - membership degree of an individual x wrt a fuzzy set S • Membership Degree Function (MDF) • Uses fuzzy formulae for Boolean operators: ║p  q║ = min({║p║, ║q║}) ║p  q║ = max({║p║, ║q║}) ║¬p║ = 1 – ║p║

4. Some Problems of FT (1) • Model: U = PERSON = {j, m}; TALL = {0.5/j, 0.3/m}; SHORT = {0.5/j, 0.7/m} • FT fails to handle tautologies / contradictions correctly E.g. ║John is tall or John is not tall║ = max({║j  TALL║, 1 – ║j  TALL║}) = 0.5

5. Some Problems of FT (2) • Model: U = PERSON = {j, m}; TALL = {0.5/j, 0.3/m}; SHORT = {0.5/j, 0.7/m} • FT fails to handle internal penumbral connections correctly • Internal Penumbral Connections: concerning the borderline cases of one vague set E.g. ║Mary is tall and John is not tall║ = min({║m  TALL║, 1 – ║j  TALL║}) = 0.3 • FT fails to handle external penumbral connections correctly • External Penumbral Connections: concerning the border lines between 2 or more vague sets E.g. ║Mary is tall and Mary is short║ = min({║m  TALL║, ║m  SHORT║}) = 0.3

6. Supervaluation Theory (ST) • Views vague concepts as truth value gaps • Evaluates truth values of sentences with vague concepts by means of admissible complete specifications (ACSs) • Complete specification – assignment of the truth value 1 or 0 to every individual wrt the vague sets in a statement • If the statement is true (false) on all ACSs, then it is true (false). Otherwise, it has no truth value.

7. Rectifying the Flaws of FT (1) • Model: U = PERSON = {j, m}; TALL = {0.5/j, 0.3/m}; SHORT = {0.5/j, 0.7/m} • An example of ACS: ║j  TALL║ = 1, ║m  TALL║ = 0, ║j  SHORT║ = 0, ║m  SHORT║ = 1 • A vague statement in the form of a tautology (contradiction) will have truth value 1 (0) under all complete specifications • ║John is tall or John is not tall║ = 1

8. Rectifying the Flaws of FT (2) • Model: U = PERSON = {j, m}; TALL = {0.5/j, 0.3/m}; SHORT = {0.5/j, 0.7/m} • Rules out all inadmissible complete specifications related to the borderline cases of one vague set: ║j  TALL║ = 0, ║m  TALL║ = 1, ║j  SHORT║ = 0, ║m  SHORT║ = 0 • ║Mary is tall and John is not tall║ = 0 • Rules out all inadmissible complete specifications related to the border lines between 2 or more vague sets: ║j  TALL║ = 1, ║m  TALL║ = 1, ║j  SHORT║ = 0, ║m  SHORT║ = 1 • ║Mary is tall and Mary is short║ = 0

9. Weakness of ST • ST cannot distinguish different degrees of vagueness because it treats all borderline cases alike as truth value gaps • We need a theory that combines FT and ST – a theory that can distinguish different degrees of vagueness and yet avoid the flaws of FT

10. Glöckner’s Method for Vague Quantifiers (VQs) • Semi-Fuzzy Quantifiers – only take crisp (i.e. non-fuzzy) sets as arguments • Fuzzy Quantifiers – take crisp or fuzzy sets as arguments • MDFs of some Semi-Fuzzy Quantifiers: • ║(about 10)(A)(B)║ = T-4,-1,1,4(|A  B| / |A| – 10) • ║every(A)(B)║ = 1, if A  B = 0, if A ¬ B

11. Quantifier Fuzzification Mechanism (QFM) • All linguistic quantifiers are modeled as semi-fuzzy quantifiers initially • QFM – transform semi-fuzzy quantifiers to fuzzy quantifiers • Q(X1, … Xn) • 1. Choose a cut level γ  (0, 1] • 2. 2 crisp sets: Xγmin = X 0.5 + 0.5γ; Xγmax= X> 0.5 – 0.5γ • 3. Family of crisp sets: Tγ(X) = {Y: Xγmin Y  Xγmax} • 4. Aggregation Formula: ║Qγ(X1, … Xn)║ = m0.5({║Q(Y1, … Yn)║: Y1 Tγ(X1), … Yn Tγ(Xn)}) m0.5(Z) = inf(Z), if |Z|  2  inf(Z) > 0.5 = sup(Z), if |Z|  2  sup(Z) < 0.5 = 0.5, if (|Z|  2  inf(Z)  0.5  sup(Z)  0.5)  (Z = ) = r, if Z = {r} • 5. Definite Integral: ║Q(X1, … Xn)║ = ∫[0, 1]║Qγ(X1, … Xn)║dγ

12. Glöckner’s Method and ST • The combination of crisp sets Y1 Tγ(X1), … Yn Tγ(Xn) can be seen as complete specifications of the fuzzy arguments X1, … Xnat the cut level γ • No need to use fuzzy formulae for Boolean operators • Can handle tautologies / contradictions correctly • To handle internal / external penumbral connections correctly, we need Modified Glöckner’s Method (MGM)

13. Handling Internal Penumbral Connections • A new definition for Family of Crisp Sets: Tγ(X) = {Y: Xγmin Y Xγmax such that for any x, y  U, if x  Y and ║x  X║  ║y  X║, then y  Y} • Model: U = PERSON = {j, m}; TALL = {0.5/j, 0.3/m}; SHORT = {0.5/j, 0.7/m} • The inadmissible complete specification ║j  TALL║ = 0, ║m  TALL║ = 1, ║j  SHORT║ = 0, ║m  SHORT║ = 0 corresponds to Y = {m} as a complete specification of TALL • ║Mary is tall and John is not tall║ = 0

14. Handling External Penumbral Connections (1) • Meaning Postulates (MPs) • E.g.TALL  SHORT =  • How to specify the relationship between the MPs and the set specifications of the model? • Complete Freedom: no constraint on the MPs and set specifications; may lead to the consequence that no ACSs of the sets can satisfy the MPs • 0 Degree of Freedom (0DF): every possible ACS of the sets should satisfy every MP; many models in practical applications are ruled out

15. Handling External Penumbral Connections (2) • 1 Degree of Freedom (1DF): Consider a model with the vague sets X1, … Xn (n  2) and a number of MPs. For every γ  (0, 1], every i (1  i  n) and every combination of Y1 Tγ(X1), … Yi–1 Tγ(Xi–1), Yi+1 Tγ(Xi+1), … Yn Tγ(Xn), there must exist at least one Yi  Tγ(Xi) such that Y1, … Yi–1, Yi, Yi+1, … Yn satisfy every MP • A new Aggregation Formula: ║Qγ(X1, … Xn)║ = m0.5({║Q(Y1, … Yn)║: Y1 Tγ(X1), … Yn Tγ(Xn) such that Y1, … Yn satisfy the MP(s)})

16. Handling External Penumbral Connections (3) • Model: U = PERSON = {j, m}; TALL = {0.5/j, 0.3/m}; SHORT = {0.5/j, 0.7/m} • MP: TALL  SHORT =  • This model and this MP satisfy the 1DF constraint • The inadmissible complete specification ║j  TALL║ = 1, ║m  TALL║ = 1, ║j  SHORT║ = 0, ║m  SHORT║ = 1 corresponds to Y1 = {j, m} as a complete specification of TALL and Y2 = {m} as a complete specification of SHORT • ║Mary is tall and Mary is short║ = 0

17. Iterated Quantifiers • Quantified statements with both subject and object can be modeled by iterated quantifiers • Eg. Every boy loves every girl. • every(BOY)({x: every(GIRL)({y: LOVE(x, y)})})

18. Iterated VQs • Q1(A1)({x: Q2(A2)({y: B(x, y)})}) • 1. For each possible x, determine {y: B(x, y)} • 2. Determine ║Q2(A2)({y: B(x, y)})║using MGM • 3. Obtain the vague set: {x: Q2(A2)({y: B(x, y)})} = {║Q2(A2)({y: B(xi, y)})║/xi, …} • 4. Calculate ║Q1(A1)({x: Q2(A2)({y: B(x, y)})})║using MGM

19. A Property of MGM • Suppose the membership degrees wrt the vague sets X1, … Xn are restricted to {0, 1, 0.5} and the truth values output by a semi-fuzzy quantifier Q with n arguments are also restricted to {0, 1, 0.5}, then ║Q(X1, … Xn)║ as calculated by MGM is the same as that obtained by the supervaluation method if we use 0.5 to represent the truth value gap. • MGM is a generalization of the supervaluation method.