Logic, Representation and Inference

1. Logic, Representation and Inference Introduction to Semantics What is semantics for? Role of FOL Montague Approach Introduction to Semantics

2. Semantics • Semantics is the study of the meaning of NL expressions • Expressions include sentences, phrases, and sentences. • What is the goal of such study? • Provide a workable definition of meaning. • Explain semantic relations between expressions. Introduction to Semantics

3. Examples of Semantic Relations • Synonymy • John killed Mary • John caused Mary to die • Entailment • John fed his cat • John has a cat • Consistency • John is very sick • John is not feeling well • John is very healthy Introduction to Semantics

4. Different Kinds of MeaningX means Y • Meaning as definition: • a bachelor means an unmarried man • Meaning as intention: • What did John mean by waving? • Meaning as reference:"Eiffel Tower " means Introduction to Semantics

5. Workable Definition of Meaning • Restrict the scope of semantics. • Ignore irony, metaphor etc. • Stick to the literal interpretations of expressions rather than metaphorical ones. (My car drinks petrol). • Assume that meaning is understood in terms of something concrete. Introduction to Semantics

6. Concrete Semantics • Procedural semantics: the meaning of a phrase or sentence is a procedure:“Pick up a big red block”(Winograd 1972) • Object–Oriented Semantics: meaning is an instance of a class. • Truth-Conditional Semantics Introduction to Semantics

7. Truth Conditional Semantics • Key Claim: the meaning of a sentence is identical to the conditions under which it is true. • Know the meaning of "Ġianni ate fish for tea" = know exactly how to apply it to the real world and decide whether it is true or false. • On this view, one task of semantic theory is to provide a system for identifying the truth conditions of sentences. Introduction to Semantics

8. TCS and Semantic Relations • TCS provides a precise account of semantic relations between sentences. • Examples: • S1 is synonymous with S2. • S1 entails S2 • S1 is consistent with S2. • S1 is inconsistent with S2. • Just like logic! • Which logic? Introduction to Semantics

9. NL Semantics: Two Basic Issues • How can we automate the process of associating semantic representations with expressions of natural language? • How can we use semantic representations of NL expressions to automate the process of drawing inferences? • We will focus mainly on first issue. Introduction to Semantics

10. Associating Semantic Representations Automatically • Design a semantic representation language. • Figure out how to compute the semantic representation of sentences • Link this computation to the grammar and lexicon. Introduction to Semantics

11. Semantic Representation Language • Logical form (LF) is the name used by logicians (Russell, Carnap etc) to talk about the representation of context-independent meaning. • Semantic representation language has to encode the LF. • One concrete representation for logical form is first order logic (FOL) Introduction to Semantics

12. Why is FOL a good thing? • Has a precise, model-theoretic semantics. • If we can translate a NL sentence S into a sentence of FOL, then we have a precise grasp on at least part of the meaning of S. • Important inference problems have been studied for FOL. Computational solutions exist for some of them. • Hence the strategy of translating into FOL also gives us a handle on inference. Introduction to Semantics

13. Anatomy of FOL • Symbols of different types • constant symbols: a,b,c • variable symbols: x, y, z • function symbols: f,g,h • predicate symbols: p,q,r • connectives: &, v,  • quantifiers: ,  • punctuation: ), (, “,” Introduction to Semantics

14. Anatomy of FOL • Symbols of different types • constant symbols: csa3180, nlp, mike, alan, rachel, csai • variable symbols: x, y, z • function symbols: lecturerOf, subjectOf • predicate symbols: studies, likes • connectives: &, v,  • quantifiers: ,  • punctuation: ), (, “,” Introduction to Semantics

15. Anatomy of FOL With these symbols we can make expressions of different types • Expressions for referring tothings • constant: alan, nlp • variable: x • term: subject(csa3180) • Expressions for stating facts • atomic formula: study(alan,csa3180) • complex formula: study(alan,csa3180) & teach(mike, csa3180) • quantified expression: xy teaches(lecturer(x),x) & studies(y,subject(x))xy likes(x,subjectOf(y))  studies(x,y) Introduction to Semantics

16. Logical Form of Phrases Introduction to Semantics

17. Logical Forms of Sentences • John kicks Fido: kick(john, fido) • Every student wrote a program xy( stud(x)  prog(y) & write(x,y)) yx(stud(x)  prog(y) & write(x,y)) • Semantic ambiguity related to quantifier scope Introduction to Semantics

18. Building Logical Form Frege’s Principle of Compositionality • The POC states that the LF of a complex phrase can be built out of the LFs of the constituent parts. • An everyday example of compositionality is the way in which the “meaning” of arithmetic expressions is computed(2+3) * (4/2) = (5 * 2) =10 Introduction to Semantics

19. Compositionality for NL • The LF of the whole sentence can be computed from the LF of the subphrases, i.e. • Given the syntactic rule X  Y Z. • Suppose [Y], [Z] are the LFs of Y, and Z respectively. • Then [X] = ([Y],[Z]) where  is some function for semantic combination Introduction to Semantics

20. Claims of Richard Montague: • Each syntax rule is associated with a semantic rule that describes how the LF of the LHS category is composed from the LF of its subconstituents • 1:1 correspondence between syntax and semantics (rule-to-rule hypothesis) • Functional composition proposed for combining semantic forms. • Lambda calculus proposed as the mechanism for describing functions for semantic combination. Introduction to Semantics

21. Sentence Rule • Syntactic Rule:S  NP VP • Semantic Rule:[S] = [VP]([NP])i.e. the LF of S is obtained by "applying" the LF of VP to the LF of NP. • For this to be possible [VP] must be a function, and [NP] the argument to the function. Introduction to Semantics

22. S write(bertrand,principia) VP y.write(y,principia) NP bertrand bertrand V x.y.write(y,x) NP principia writes principia Parse Tree with Logical Forms Introduction to Semantics