Foundations of Computational Linguistics: Human-Computer Communication in Natural Language

The author begins with the concept of a language, which is defined as a set of word sequences with a formal language being a subset of the free monoid over a finite lexicon. The reasons for using generator grammars are discussed but these need to be replaced by a special type called categorial (C-) grammar, invented in the 1930's and applied to natural languages in the 1950's. The disadvantages of C-grammar are outlined by the author.

A second generative grammar, called phase structure (PS) grammar is discussed, and restrictions on the rule schema give four different types of PS-grammars. These different types give four different classes of complexity, with this complexity measured by an algorithm with the number of primitive operations required to analyze an input expression counted in relation to length of the input. Context-free PS-grammar is applied to natural language via phrase structures. The author distinguishes carefully the differences between C- and PS-grammars. In particular, the goal of PS-grammar is to represent what is called the constituent structure of natural language, which is defined by the author as a formal property of phase structures. He makes it very clear that there is as of yet no complete PS-grammars for natural languages. He also discusses in detail the constituent structure paradox with examples of discontinuous elements in natural language. The solution of Chomsky to this problem via transformation rules is outlined. This transformational grammar is equivalent to a Turing machine generating recursively enumerable languages and so is undecidable. To resolve this, Chomsky introduced formal restrictions on the transformations called "recoverability of deletions". The author shows however via Bach-Peters sentences, that this method does not always work. The discussion of parsing distinguishes between morphology parsers, syntax parsers, and semantic parsers. This exemplifies how the declarative-procedural distinction applies to the relation between generative grammars and parsers. These distinctions are important, the author argues, when modeling natural languages on a computer.

That natural languages are not context-free motivates the author to search for other formalisms. A successful formalism must be computationally tractable, and this is reflected in its grammar type. The "type transparency" between the parser and the grammar enables the analysis of the complexity to be done at the parser, since for any language, they will have the same formal grammar. The weaknesses of this approach for PS-grammar is discussed in detail by the author, and he gives other algorithms that restructure the PS-grammar rules in order to obtain parsing of context-free languages. These concerns also exist when the requirement that the grammar formalism "input-output" be equivalent to what is spoken and heard. PS-grammar is shown to be incompatible with this.

The more recent notion of left-associative (LA) grammar is discussed as an alternative to C-and PS-grammars. The irregular bracketing of these grammars is handled by using the principle of possible continuations in LA-grammars. The author shows, interestingly, that the distinction between context-free and context-sensitive languages disappears in LA-grammar. The principle of possible continuations allows close relation between parsing and generation. Discontinuous elements are dealt with by coding filler positions into a functor category and then cancelled later.

There are different types of LA-grammars which are characterized in terms of their generative capacity and computational complexity. Recursion theory plays a role, and the complexity is measured in terms of the operations required to process an input in the worst case. The author discusses in detail the different types of LA grammars and their subhierarchies, and compares the LA-and PS-hierarchies.

The morphological analysis of natural language can be studied in terms of combination principles, with words being defined in terms of word forms, and a clear distinction is made between the two notions. Word forms in turn are composed of elementary parts called morphemes, and morphemes are associated analyzed allomorphs. The author explains the steps needed to morphologically analyze an unknown word.

Even more interesting, and more important from a practical point of view, the author discusses methods for automatic word form recognition, including methodologies for investigating the frequency distribution of words. The grammar system of LA-morphology is used for word form recognition of English, German, Italian, French, Japanese, and Polish. The empirical testing of a grammar system via the building of a corpora is discussed with an illustration of Zipf's law. Unfortunately, the author does not discuss in detail the use of hidden Markov models in statistical tagging.

Syntax deals with the composition of word forms and uses the combination rules of valency, agreement, and word order. German and English are analyzed in terms of their word order. The ability of LA-grammar to map variable-based rule patterns onto categorially analyzed input expressions using a strictly time-linear order makes it efficient and flexible, argues the author. The LA-syntax for English and German is discussed in detail by the author. The discussion makes heavy use of finite state machines.

There are three different semantic systems, namely the logical, programming, and natural languages, and the author shows how these are related via replication, reconstruction, transfer, and composition. The problems in viewing natural languages as logical semantics is discussed in the context of Tarski's work. The author argues that the insistence of using logical semantics for analyzing natural language is incorrect since natural languages work differently from metalanguage-dependent logical languages. Truth, meaning, and ontology are taken out of the philosophical realm and applied to the logical semantics of natural language.