Journal article

Publication year: 2022

Journal: Brain Sciences

Volume number: 12

Issue number: 5

Open access status: Gold

DOI Link: https://doi.org/10.3390/brainsci12050667

Publisher: MDPI

Abstract: 

Plants and animals are among the most behaviorally significant superordinate categories for humans. Visually assigning objects to such high-level classes is challenging because highly distinct items must be grouped together (e.g., chimpanzees and geckos) while more similar items must sometimes be separated (e.g., stick insects and twigs). As both animals and plants typically possess complex multi-limbed shapes, the perceptual organization of shape into parts likely plays a crucial rule in identifying them. Here, we identify a number of distinctive growth characteristics that affect the spatial arrangement and properties of limbs, yielding useful cues for differentiating plants from animals. We developed a novel algorithm based on shape skeletons to create many novel object pairs that differ in their part structure but are otherwise very similar. We found that particular part organizations cause stimuli to look systematically more like plants or animals. We then generated other 110 sequences of shapes morphing from animal- to plant-like appearance by modifying three aspects of part structure: sprouting parts, curvedness of parts, and symmetry of part pairs. We found that all three parameters correlated strongly with human animal/plant judgments. Together our findings suggest that subtle changes in the properties and organization of parts can provide powerful cues in superordinate categorization.

Harvard Citation style: Tiedemann, H., Schmidt, F. and Fleming, R. (2022) Superordinate Categorization Based on the Perceptual Organization of Parts, Brain Sciences, 12(5), Article 667. https://doi.org/10.3390/brainsci12050667

APA Citation style: Tiedemann, H., Schmidt, F., & Fleming, R. (2022). Superordinate Categorization Based on the Perceptual Organization of Parts. Brain Sciences. 12(5), Article 667. https://doi.org/10.3390/brainsci12050667