English

A Physical Metaphor to Study Semantic Drift

Computation and Language 2016-08-04 v1 Neural and Evolutionary Computing Machine Learning

Abstract

In accessibility tests for digital preservation, over time we experience drifts of localized and labelled content in statistical models of evolving semantics represented as a vector field. This articulates the need to detect, measure, interpret and model outcomes of knowledge dynamics. To this end we employ a high-performance machine learning algorithm for the training of extremely large emergent self-organizing maps for exploratory data analysis. The working hypothesis we present here is that the dynamics of semantic drifts can be modeled on a relaxed version of Newtonian mechanics called social mechanics. By using term distances as a measure of semantic relatedness vs. their PageRank values indicating social importance and applied as variable `term mass', gravitation as a metaphor to express changes in the semantic content of a vector field lends a new perspective for experimentation. From `term gravitation' over time, one can compute its generating potential whose fluctuations manifest modifications in pairwise term similarity vs. social importance, thereby updating Osgood's semantic differential. The dataset examined is the public catalog metadata of Tate Galleries, London.

Keywords

Cite

@article{arxiv.1608.01298,
  title  = {A Physical Metaphor to Study Semantic Drift},
  author = {Sándor Darányi and Peter Wittek and Konstantinos Konstantinidis and Symeon Papadopoulos and Efstratios Kontopoulos},
  journal= {arXiv preprint arXiv:1608.01298},
  year   = {2016}
}

Comments

8 pages, 4 figures, to appear in Proceedings of SuCCESS-16, 1st International Workshop on Semantic Change & Evolving Semantics

R2 v1 2026-06-22T15:11:31.283Z