Tonal Cognition

: This article presents a self‐organizing map (SOM) neural network model of tonality based on experimentally quantified tonal hierarchies. A toroidal representation of key distances is recovered in which keys are located near their neighbors on the circle of fifths, and both parallel and relative ma...

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Veröffentlicht in:	Annals of the New York Academy of Sciences 2001-06, Vol.930 (1), p.77-91
Hauptverfasser:	KRUMHANSL, CAROL L., TOIVIAINEN, PETRI
Format:	Artikel
Sprache:	eng
Schlagworte:	Cognition Humans Models, Theoretical Music Music - psychology Neural Networks (Computer) Pitch Perception Probe tone Time Perception Tonality
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creator	KRUMHANSL, CAROL L. TOIVIAINEN, PETRI
description	: This article presents a self‐organizing map (SOM) neural network model of tonality based on experimentally quantified tonal hierarchies. A toroidal representation of key distances is recovered in which keys are located near their neighbors on the circle of fifths, and both parallel and relative major/minor key pairs are proximal. The map is used to represent dynamic changes in the sense of key as cues to key become more or less clear and modulations occur. Two models, one using tone distributions and the other using tone transitions, are proposed for key‐finding. The tone transition model takes both pitch and temporal distance between tones into account. Both models produce results highly comparable to those of musically trained listeners, who performed a probe tone task for ten nine‐chord sequences. A distributed mapping of tonality is used to visualize activation patterns that change over time. The location and spread of this activation pattern is similar for experimental results and the key‐finding model.
doi_str_mv	10.1111/j.1749-6632.2001.tb05726.x
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subjects	Cognition Humans Models, Theoretical Music Music - psychology Neural Networks (Computer) Pitch Perception Probe tone Time Perception Tonality
title	Tonal Cognition
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