Abstract
Advanced perceptual systems are faced with the problem
of securing a principled (ideally, veridical) relationship between the
world and its internal representation. I propose a unified approach
to visual representation, addressing the need for superordinate and
basic-level categorization and for the identification of specific
instances of familiar categories. According to the proposed theory,
a shape is represented internally by the responses of a small number
of tuned modules, each broadly selective for some reference shape,
whose similarity to the stimulus it measures. This amounts to
embedding the stimulus in a low-dimensional proximal shape space
spanned by the outputs of the active modules. This shape space
supports representations of distal shape similarities that are
veridical as Shepard's (1968) second-order isomorphisms
(i.e., correspondence between distal and proximal similarities
among shapes, rather than between distal shapes and their proximal
representations). Representation in terms of similarities to reference
shapes supports processing (e.g., discrimination) of shapes that are
radically different from the reference ones, without the need for the
computationally problematic decomposition into parts required by other
theories. Furthermore, a general expression for similarity between two
stimuli, based on comparisons to reference shapes, can be used to
derive models of perceived similarity ranging from continuous,
symmetric, and hierarchical ones, as in multidimensional scaling
(Shepard 1980), to discrete and nonhierarchical ones, as in the
general contrast models (Shepard & Arabie 1979; Tversky
1977).
Publisher
Cambridge University Press (CUP)
Subject
Behavioral Neuroscience,Physiology,Neuropsychology and Physiological Psychology
Cited by
267 articles.
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