 | Algebraic Structures in Natural Language Subjects: Computer Science; Engineering & Technology; Humanities; Language & Literature; Mathematics & Statistics; Algorithms & Complexity; Artificial Intelligence; Computation; Computer Science (General); Language & Linguistics; Legal Ethical & Social Aspects of IT; Systems & Control Engineering; Philosophy; Advanced Mathematics; Cognitive Artificial Intelligence.; Computational Linguistic & Language Recognition; Machine Learning - Design; Neural Networks; Algorithms & Complexity; Social Aspects of Computing & IT; Machine Learning; Philosophy of Language; Linguistics; Algebra; Algebraic Structures in Natural Language addresses a central problem in cognitive science, concerning the learning procedures through which humans acquire and represent natural language. Until recently algebraic systems have dominated the study of natural language in formal and computational linguistics, AI, and the of psychology of language, with linguistic knowledge seen as encoded in formal grammars, model theories, proof theories, and other rule driven devices, and researchers drawing conclusions about how humans acquire and represent language. Recent work on deep learning has produced an increasingly powerful set of general learning mechanisms which do not apply algebraic models of representation (although they can be combined with them), and success in NLP in particular has led some researchers to question the role of algebraic models in the study of human language acquisition and linguistic representation. Psychologists and cognitive scientists have also been exploring explanations of language evolution and language acquisition that rely on probabilistic methods, social interaction, and information theory, rather than on formal models of grammar induction. This work has also led some researchers to question the centrality of algebraic approaches to linguistic representation. This book addresses the learning procedures through which humans acquire natural language, and the way in which they represent its properties. It brings together leading researchers from computational linguistics, psychology, behavioural science, and mathematical linguistics to consider the significance of non-algebraic methods for the study of natural language, and represents a wide spectrum of views, from the claim that algebraic systems are largely irrelevant, to the contrary position that non-algebraic learning methods are engineering devices for efficiently identifying the patterns that underlying grammars and semantic models generate for natural language input. There are interesting and important perspectives that fall at intermediate points between these opposing approaches, and they may combine elements of both. It will appeal to researchers and advanced students in each of these fields, as well as to anyone who wants to learn more about the relationship between algorithms and language. Shalom Lappin is Professor of Computational Linguistics at the University of Gothenburg, Professor of Natural Language Processing at Queen Mary University of London, and Emeritus Professor of Computational Linguistics at King's College London. His research focuses on the application of machine learning and probabilistic models to the representation and the acquisition of linguistic knowledge. Jean-Philippe Bernardy is a researcher at the University of Gothenburg. His main research interest is in interpretable linguistic models, in particular those built from first principles of algebra, probability, and geometry. |
