Abstract
The optimality of multidimensional perceptual categorization performance was examined for several base-rate ratios, for both integral and separable dimension stimuli, and for complex category structures. In all cases, the optimal decision bound was highly nonlinear. Observers completed several experimental sessions, and all analyses were performed at the single-observer level using a series of nested models derived from decision-bound theory (Maddox, 1995; Maddox & Ashby, 1993). In every condition, all observers were found to be sensitive to the base-rate manipulations, but the majority of observers appeared to overestimate the base-rate difference. These findings converge with those for cases in which the optimal decision bound was linear (Maddox, 1995) and suggest that base-rates are learned in a similar fashion regardless of the complexity of the optimal decision bound. Possible explanations for the consistent overestimate of the base-rate difference are discussed. Several continuous-valued analogues of Kruschke’s (1996) theory of base-rate learning with discrete-valued stimuli were tested. These models found some support, but in all cases were outperformed by a version of decision-bound theory that assumed accurate knowledge of the category structure and an overestimate of the base-rate difference.
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This research was supported in part by an Arizona State University Faculty-Grant-in-Aid, an Arizona State University Research Incentive Award, and by National Science Foundation Grant SBR-9514331.
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Maddox, W.T., Bohil, C.J. Overestimation of base-rate differences in complex perceptual categories. Perception & Psychophysics 60, 575–592 (1998). https://doi.org/10.3758/BF03206047
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DOI: https://doi.org/10.3758/BF03206047