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Statistical Learning of Unfamiliar Sounds as Trajectories Through a Perceptual Similarity Space
Cognitive Science 43 (8):e12740 (2019)
Abstract
In typical statistical learning studies, researchers define sequences in terms of the probability of the next item in the sequence given the current item (or items), and they show that high probability sequences are treated as more familiar than low probability sequences. Existing accounts of these phenomena all assume that participants represent statistical regularities more or less as they are defined by the experimenters—as sequential probabilities of symbols in a string. Here we offer an alternative, or possibly supplementary, hypothesis. Specifically, rather than identifying or labeling individual stimuli discretely in order to predict the next item in a sequence, we need only assume that the participant is able to represent the stimuli as evincing particular similarity relations to one another, with sequences represented as trajectories through this similarity space. We present experiments in which this hypothesis makes sharply different predictions from hypotheses based on the assumption that sequences are learned over discrete, labeled stimuli. We also present a series of simulation models that encode stimuli as positions in a continuous two‐dimensional space, and predict the next location from the current location. Although no model captures all of the data presented here, the results of three critical experiments are more consistent with the view that participants represent trajectories through similarity space rather than sequences of discrete labels under particular conditions.My notes
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Citations of this work
Statistical learning of syllable sequences as trajectories through a perceptual similarity space.Wendy Qi & Jason D. Zevin - 2024 - Cognition 244 (C):105689.
Computational Modeling of the Segmentation of Sentence Stimuli From an Infant Word‐Finding Study.Daniel Swingley & Robin Algayres - 2024 - Cognitive Science 48 (3):e13427.
Perceptual intake explains variability in statistical word segmentation.Felix Hao Wang, Meili Luo & Suiping Wang - 2023 - Cognition 241 (C):105612.
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Segmentation of the speech stream in a non-human primate: statistical learning in cotton-top tamarins.Marc D. Hauser, Elissa L. Newport & Richard N. Aslin - 2001 - Cognition 78 (3):B53-B64.
Modeling human performance in statistical word segmentation.Michael C. Frank, Sharon Goldwater, Thomas L. Griffiths & Joshua B. Tenenbaum - 2010 - Cognition 117 (2):107-125.
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